# Search Results for equation*

## Biographies

1. Erland Bring (1736-1798)
• This work describes Bring's contribution to the algebraic solution of equations.
• In the year 1786 Erland Samuel Bring, Professor at the University of Lund in Sweden, showed how by an extension of the method of Tschirnhausen it was possible to deprive the general algebraical equation of the 5th degree of three of its terms without solving an equation higher than the 3rd degree.
• [Bring's "Reduction of the Quintic Equation" was republished by the Rev.
• Bring discovered an important transformation to simplify a quintic equation.
• It enabled the general quintic equation to be reduced to one of the form .
• He begins with the quadratic equation x2 + mx + n = 0 and makes the substitution x + a + y = 0 where a = m/2 and y2 = m2/4 - n.
• This substitution allows the second highest term in the original equation to be eliminated.
• In fact, this substitution will eliminate the second highest term for any equation.
• Bring then considers the general cubic equation x3 + mx2 + nx + p = 0.
• writes down without a proof an explicit equation for y.
• Bring finds that a linear equation between a and b and a quadratic equation for b gives an equation y3 = const.
• He then goes on to apply the same techniques to quartic equations before moving on to the quintic.
• Here he is able to apply the same ideas but this time he cannot eliminate all the lower order terms but the best he can do is to reduce the equation to one of the form x5 + px + q = 0.
• Now, of course, he has presented a method to solve algebraic equations up to degree 4 and he ends his paper by asking the reader to compare his method for the cubic and the quartic with that given by Cardan and decide for himself which is the most interesting.
• By the time Jerrard discovered the transformation, Ruffini's work and Abel's work on the impossibility of solving the quintic and higher order equations had been published.
• However, at the time of Bring's discovery, there was no hint that the quintic could not be solved by radicals and, although Bring does not claim that he discovered his transformation in an attempt to solve the quintic, it is likely that this is in fact why he was examining quintic equations.
• In a report contained in the 'Proceedings of the British Association' for 1836, Sir William Hamilton showed that Mr Jerrard was mistaken in supposing that the method was adequate to taking away more than three terms of the equation of the 5th degree, but supplemented this somewhat unnecessary refutation of a result, known 'a priori' to be impossible, by an extremely valuable discussion of a question raised by Mr Jerrard as to the number of variables required in order that any system of equations of given degrees in those variables shall admit of being satisfied without solving any equation of a degree higher than the highest of the given degrees.
• In the year 1886 the senior author of this memoir [Sylvester] showed in a paper in Kronecker's (better known as Crelle's) 'Journal' that the trinomial equation of the 5th degree, upon which by Bring's method the general equation of that degree can be made to depend, has necessarily imaginary coefficients except in the case where four of the roots of the original equation are imaginary, and also pointed out a method of obtaining the absolute minimum degree M of an equation from which any given number of specified terms can be taken away subject to the condition of not having to solve any equation of a degree higher than M.
• The numbers furnished by Hamilton's method, it is to be observed, are not minima unless a more stringent condition than this is substituted, viz., that the system of equations which have to be resolved in order to take away the proposed terms shall be the simplest possible, i.e., of the lowest possible weight and not merely of the lowest order; in the memoir in 'Crelle,' above referred to, he has explained in what sense the words weight and order are here employed.
• He has given the name of Hamilton's Numbers to these relative minima (minima, i.e., in regard to weight) for the case where the terms to be taken away from the equation occupy consecutive places in it, beginning with the second.
• The deep significance of the Bring-Jerrard transformation was ascertained only after Charles Hermite (1858) used the above-mentioned trinomial form for the solution of fifth-degree equations with the aid of elliptic modular functions, thereby laying the foundations for new methods of studying and solving equations of higher degrees with the aid of transcendental functions.
• History Topics: Quadratic, cubic and quartic equations .

2. Marek Kuczma (1935-1991)
• For example in the student years he published papers such as: (with Stanisław Golab and Z Opial) La courbure d'une courbe plane et l'existence d'une asymptote Ⓣ (1958), On convex solutions of the functional equation g[a(x)] - g(x) = j(x) (1959), On the functional equation j(x) + j [f (x)] = F(x) (1959), On linear differential geometric objects of the first class with one component (1959), Bemerkung zur vorhergehenden Arbeit von M Kucharzewski Ⓣ (1959), Note on convex functions (1959), and (with Jerzy Kordylewski) On some functional equations (1959).
• On 1 December 1966, in addition to these position which he continued to hold, Kuczma became head of the Department of Functional Equations at Katowice.
• From the founding of the new University, Kuczma became the head of the mathematics section and head of the department of functional equations.
• In fact he published around 30 papers during the 1980s despite his severe disability and in [',' B Choczewski, Papers of Marek Kuczma written in the last decade of his life, in Selected topics in functional equations and iteration theory, Graz, 1991 (Karl-Franzens-Univ.
• The first of these Functional equations in a single variable appeared in 1968 and was the first book to be written on this topic.
• This is the first book ever published on functional equations in a single variable ..
• The related questions of commuting functions, continuous iteration, and Schroder's and Abel's functional equations are also treated.
• Kuczma's second book was An introduction to the theory of functional equations and inequalities.
• Cauchy's equation and Jensen's inequality published in 1985.
• Probably even the most devoted specialist would not have thought that about 300 pages can be written just about the Cauchy equation (and on some closely related equations and inequalities).
• In the opinion and experience of this reviewer this is a very useful book and a primary reference not only for those working in functional equations, but mainly for those in other fields of mathematics and its applications who look for a result on the Cauchy equation and/or the Jensen inequality.
• His final book Iterative functional equations was written jointly with Bogdan Choczewski and Roman Ger who had worked for his doctorate with Kuczma at the Silesian University of Katowice, graduating in 1971.
• The book is a cohesive and exhaustive account of contemporary theory of iterative functional equations.
• Fundamental notions such as existence and uniqueness of solutions of equations under consideration are treated throughout the book as well as a surprisingly wide scale of examples showing applications of the theory in dynamical systems, ergodic theory, functional analysis, functional equations in several variables, functional inequalities, geometry, iteration theory, ordinary differential equations, partial differential equations, probability theory and stochastic processes.
• the paramount achievement of Professor Marek Kuczma was the creation and development of a systematic theory of iterative functional equations and founding a mathematical school centred around the seminar conducted by him since October 1964.
• Kuczma was considered an outstanding mathematician highly esteemed by the international community of specialists; among the functional equationists he had commonly been treated as one of the informal leaders.

3. Luis Caffarelli (1948-)
• Shortly after my arrival, I attended a fascinating series of lectures by Hans Lewy and became interested in nonlinear partial differential equations, variations inequalities and free-boundary problems.
• If the balloon were suspended freely in the air, a first approximation to its shape would be given by a prescribed mean curvature equation (a mildly non-linear equation) that we could deduce from the fact that the balloon tries to minimise the energy of the configuration (an unconstrained variational problem).
• If constrained to lie inside the box, the surface of the balloon would behave differently when it is free than when it presses against the wall (a strongly nonlinear differential equation) creating a separation curve (the free boundary) between both regions.
• In 1980 I was invited to join the faculty at the Courant Institute, where I developed new interests: fluid dynamics and fully nonlinear equations under the advice and in collaboration with Louis Nirenberg.
• mean curvature equation, Monge-Ampere equation in real or complex space, etc.).
• for his deep and fundamental work in nonlinear partial differential equations, in particular his work on free boundary problems, vortex theory and regularity theory.
• for his important contributions to the theory of nonlinear partial differential equations.
• for his work on partial differential equations.
• Free boundary problems are about finding the solution to an equation and the region where the equation holds.
• A second fundamental contribution by Caffarelli is the study of fully nonlinear elliptic partial differential equations (including the famous Monge-Ampere equation), which he revolutionised.
• The upshot is that, although the equations are nonlinear, they behave for purposes of regularity as if they were linear.
• Another fundamental contribution by Caffarelli is his joint work with Kohn and Nirenberg on partial regularity of solutions of the incompressible Navier-Stokes equation in 3 space dimensions.
• Caffarelli has also produced deep work on homogenisation and on equations with nonlocal dissipation.
• Caffarelli is the world's leading expert on regularity of solutions of partial differential equations.
• Luis Angel Caffarelli, The University of Texas at Austin, is being recognised for seminal contributions in regularity theory of nonlinear partial differential equations, free boundary problems, fully nonlinear equations, and nonlocal diffusion.
• for his groundbreaking work on partial differential equations, including creating a theory of regularity for nonlinear equations such as the Monge-Ampere equation, and free-boundary problems such as the obstacle problem, work that has influenced a whole generation of researchers in the field.
• Luis Caffarelli works in non linear analysis, mainly on non linear partial differential equations arising from geometry and mechanics.
• Another area of research is fully non linear equations and optimal transportation.
• Fully non linear equations arise in optimization and optimal control.

4. George Jerrard (1804-1863)
• His most important work Mathematical Researches (1832-35) is a 3-volume treatise on the theory of equations.
• Francois Viete and Girolamo Cardan had shown how to transform an equation of degree n so that it had no term in xn-1.
• These methods were, to a large extent, motivated by attempts to solve equations algebraically.
• Niels Abel and Paolo Ruffini showed this was impossible for general equations of degree greater than four.
• In the year 1786 Erland Samuel Bring, Professor at the University of Lund in Sweden, discovered that by the method of Tschirnhausen it was possible to deprive the general algebraical equation of the 5th degree of three of its terms without solving an equation higher than the 3rd degree.
• In fact Jerrard generalised Bring's result to show that a transformation could be applied to an equation of degree n to remove the terms in xn-1, xn-2 and xn-3.
• Charles Hermite used Jerrard's result saying that it was the most important step in studying the quintic equation since Abel's results.
• Jerrard wrote a further two-volume work on the algebraic solution of equations An essay on the resolution of equations (1858).
• Jerrard believed that he had successfully shown that quintic equations could be solved by the 'method of radicals' despite proofs that this was impossible.
• In a report contained in the 'Proceedings of the British Association' for 1836, Sir William Hamilton showed that Mr Jerrard was mistaken in supposing that the method was adequate to taking away more than three terms of the equation of the 5th degree, but supplemented this somewhat unnecessary refutation by a profound and original discussion of a question raised by Mr Jerrard, as to the number of variables required in order that any system of equations of given degrees in those variables shall admit of being satisfied without solving any equation of a degree higher than the highest of the given degrees.
• Jerrard continued to believe that he was correct and wrote in An essay on the resolution of equations (1858):- .
• What, then, it may be asked, is the element omitted by Ruffini, Abel, and other distinguished mathematicians, who have been led to the conclusion that it is not possible in every case to effect the algebraical resolution of equations of the fifth degree? Let us for a moment consider the nature of the difficulty which had to be overcome.
• It is clear that an expression for a root of the general equation of the fifth degree must involve radicals characterised by each of the symbols 2√, 3√, 5√.
• If, however, we examine all the solutions which have hitherto been discovered of particular equations of that degree, we shall find that into none of them do cubic radicals enter.
• In fact Jerrard produced his cubic radical from an equation of degree six.
• This equation of degree six was correct but his belief that it could always be solved was not.
• Among mathematicians there are those who will lend but an academic faith to Mr Jerrard's assertion that he has succeeded in rescuing from the class of impossible problems the noted problem of equations.
• Harley, like Jerrard, worked almost exclusively on quintic equations.
• I may have written its coefficients wrongly and will look at them again and again, or even solve the equation before communicating it.
• Jerrard's paper on the resolution of equations .

5. Jacopo Riccati (1676-1754)
• Rather the reverse, he was interested in all scholarly subjects as Sergio Bittanti points out in [',' S Bittanti, Count Riccati and the early days of the Riccati equation, in S Bittanti, A J Laub, J C Willems (eds.), The Riccati equation (Springer Verlag, Berlin, 1991), 1-10.','6]:- .
• Sergio Bittanti writes [',' S Bittanti, Count Riccati and the early days of the Riccati equation, in S Bittanti, A J Laub, J C Willems (eds.), The Riccati equation (Springer Verlag, Berlin, 1991), 1-10.','6]:- .
• While in the Val di Sole Riccati met with Nicolaus(II) Bernoulli and they had mathematical discussions regarding solving differential equations.
• Riccati's life-long passion for studying methods of solving differential equations using separation of variables came through his reading of this book.
• The subject of this scientific exchange is, first, a method of Riccati for separating the indeterminates in some differential equations, and then a question on the lunules quarrables which was disputed between Suzzi, one of Riccati's young disciples, and Daniel Bernoulli in 1724.
• However, he is best known for his work on solving differential equations.
• In the study of differential equations his methods of lowering the order of an equation and separating variables were important.
• He considered many general classes of differential equations and found methods of solution which were widely adopted.
• He is chiefly known for the Riccati differential equation of which he made elaborate study and gave solutions for certain special cases.
• Although he probably began studying the equation in 1715, the first written record of the differential equation seems to be in a letter he wrote to Giovanni Rizzetti in 1720.
• The equation was discussed by Riccati in the 1722-23 lecture notes we mentioned above [',' A Natucci, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1]:- .
• In expounding the known methods of integration of first-order differential equations, Riccati studied those equations that may be integrated with appropriate algebraic transformation before considering those that require a change of variable.
• He then discussed certain devices suggested by Johann Bernoulli and expounded the method used by Gabriele Manfredi to integrate homogeneous equations.
• Of these, one involves the reduction of the equation to a homogeneous one, while another more interesting method is that of "halved separation," as Riccati called it.
• In the first, the entire equation is multiplied or divided by an appropriate function of the unknown so that it becomes integrable; second, after this integration has been carried out, the result is considered to be equal to a new unknown, and one of the original variables is thus eliminated; and finally, the first two procedures are applied to the result until a new and desired result is attained.
• His work had a wide influence on leading mathematicians such as Daniel Bernoulli, who studied the equation in his Exercitationes quaedam mathematicae Ⓣ, and Leonard Euler who extended Riccati's ideas to integration of non-homogeneous linear differential equations of any order.
• Bittanti describes the end of Riccati's life [',' S Bittanti, Count Riccati and the early days of the Riccati equation, in S Bittanti, A J Laub, J C Willems (eds.), The Riccati equation (Springer Verlag, Berlin, 1991), 1-10.','6]:- .

6. Solomon Grigoryevich Mikhlin (1908-1990)
• The book [',' S G Mikhlin, Multidimensional singular integrals and integral equations, International Series of Monographs in Pure and Applied Mathematics 83 (Pergamon Press, Oxford-London-Edinburgh-New York-Paris-Frankfurt, 1965).','1] is dedicated to her memory.
• In 1966 Miklin and Maz'ya launched a Tuesday seminar on integral and partial differential equations at MatMekh.
• The first one is based upon the so-called complex Green's function and the reduction of the related boundary value problem to integral equations.
• As a result of his study of this problem, Mikhlin also gave a new invariant form of the basic equations of the theory.
• Perhaps, his most important contributions are his works on the theory of singular integral operators and singular integral equations: he is one of the founders of the multi-dimensional theory, jointly with Francesco Tricomi and Georges Giraud.
• Mikhlin was the first to develop a theory of singular integral equations as a theory of operator equations in function spaces L2.
• He established Fredholm's theorems for singular integral equations and systems of such equations under the hypothesis of non-degeneracy of the symbol.
• He also proved that the index of a single singular integral equation in the Euclidean space is zero.
• In 1961 Mikhlin developed a theory of multidimensional singular integral equations on Lipschitz spaces which are widely used in the theory of one-dimensional singular integral equations.
• Namely, he obtained basic properties of this kind of singular integral equations as a by-product of the Lp-space theory of these equations.
• A complete collection of his results in this field up to 1965, as well as contributions by Francesco Tricomi, Georges Giraud, Alberto Calderon and Antoni Zygmund, is contained in the monograph [',' S G Mikhlin, Multidimensional singular integrals and integral equations, International Series of Monographs in Pure and Applied Mathematics 83 (Pergamon Press, Oxford-London-Edinburgh-New York-Paris-Frankfurt, 1965).','1].
• Mikhlin's multiplier theorem is widely used in different branches of mathematical analysis, particularly in the theory of differential equations.
• Four Mikhlin papers, published in the period 1940-1942, deal with applications of the method of potentials to the mixed problem for the wave equation.
• In particular, he solved the mixed problem for the two-space dimensional wave equation in the half-plane by reduction to the planar Abel integral equation.
• For a planar domain with a sufficiently smooth curvilinear boundary, he reduced the problem to an integro-differential equation, which he is able to solve when the given boundary is analytic.
• In 1951 Mikhlin proved the convergence of the Schwarz alternating method for second order elliptic equations.
• He also applied methods of functional analysis, at the same time as Mark Vishik but independently of him, to the investigation of boundary value problems for degenerate second order elliptic partial differential equations.
• Mikhlin also studied the finite element approximation in weighted Sobolev spaces related to the numerical solution of degenerate elliptic equations.
• The fourth branch of his research in numerical mathematics is a method for solving Fredholm integral equations which he called the "resolvent method".
• This eliminates the need to construct and solve large systems of equations.

7. Carlo Cercignani (1939-2010)
• The papers Elementary solutions of the linearized gas-dynamics Boltzmann equation and their application to the slip-flow problem and Solutions of linearized gas-dynamics Boltzmann equation and application to slip-flow problem appeared in print in 1962 while, in the following year, he published further papers, including two written jointly with his physics advisor Sergio Albertoni, namely Numerical Evaluation of the Slip Coefficient and Slip-coefficient expression is derived using an exact analytical solution of the slip flow problem.
• As a mathematician, Cercignani obtained important results in the theory of Partial Differential Equations, Semigroup Theory, Monte-Carlo Methods, Spectral Theory, Riemann-Hilbert Problems, Fourier Analysis, and Functional Analysis.
• Cercignani devoted a particular attention to the H-theorem, and to the problem of how macroscopic, irreversible evolution equations can follow from microscopic, reversible motion equations.
• Cercignani has been one of the most active researchers of the Boltzmann equation and related topics.
• In 1975 he published his most famous treatise 'The Boltzmann equation and its applications', which collects and unifies numerous results on the Boltzmann equation previously scattered in hundreds of references.
• During the 1980's, he studied the evaporation-condensation interface between a gas and a liquid, stating an important conjecture for the long-time behaviour of the Boltzmann equation solutions.
• Let us note the diverse fields to which he contributed: to the kinetic theory of rarefied gases, models of turbulence, the transport of neutrons and of semiconductors, the Boltzmann equation and its applications which have proved useful in nanotechnology.
• Almost all of these show Carlo's passion for the Boltzmann equation, and more generally everything related to Boltzmann.
• In 45 years of research, the Boltzmann equation led Carlo to work in theoretical mechanics, partial differential equations, numerical analysis, semigroup theory, spectral theory, Riemann-Hilbert problems, Fourier analysis, and many other areas.
• A few years ago, a collaboration with Sasha Bobylev on self-similar solutions of the Boltzmann equation even led him to a new pretty formula for the inversion of the Laplace transform.
• An early classic was Theory and Application of the Boltzmann Equation (1975).
• The Boltzmann equation connects the discrete motion of the individual particles in a gas with the continuous motion of the gas as a whole.
• As with many "basic" equations, its Achilles' heel is its complexity.
• He updated this book thirteen years later, publishing it under the slightly revised title The Boltzmann Equation and its Applications (1988).
• This book gives a complete exposition of the present status of the theory of the Boltzmann equation and its applications.
• The Boltzmann equation, an integro-differential equation established by Boltzmann in 1872 to describe the state of a dilute gas, still forms the basis for the kinetic theory of gases.
• But the main exposition is tied to the classical equation established by Boltzmann.
• Dorfman, reviewing the book, writes [',' J R Dorfman, Review: The Boltzmann Equation and its Applications by Carlo Cercignani, SIAM Review 31 (2) (1989), 339-340.','5]:- .
• I believe that Cercignani has done us all an enormous service by providing books with a high level of clarity such as this one, and I recommend it for anyone interested in the Boltzmann equation.
• The scientific work of Carlo Cercignani in fluid mechanics is dominated by a significant contribution to the kinetic theory of gases and the properties of the Boltzmann equation.

8. Gianfrancesco Malfatti (1731-1807)
• He was interested in the solution of algebraic equations and he wrote two articles on this topic which he sent to his former professor Vincenzo Riccati.
• What Malfatti wanted to achieve was to solve algebraically equations of degree greater than four.
• It had been over 200 years since Cardan had published his great work Ars Magna which had given methods, devised by del Ferro, Tartaglia and Ferrari, to solve all cubic and quartic equations by radicals and Malfatti set about the task of extending the methods to equations of the fifth degree.
• In this paper, from a general equation of degree five, Malfatti produced a resolvent of degree six, now sometimes called "the resolvent of Malfatti".
• In general, of course, an equation of degree six seemed worse than the original equation of degree five but in fact this led to certain equations of degree five being able to be solved by radicals.
• This was a step forward and, nearly 100 years later, Francesco Brioschi was able to use Malfatti's resolvent to show that every equation of degree five can be solved using transcendental functions.
• The equation ydx = dy has an infinite number of integrals even under the restriction that x = 0 when y = 1.
• For any constant n, e{nx}= yngives rise to the differential equation ydx = dy.
• As we have seen above, Malfatti wrote an important work on equations of the fifth degree.
• In 1799 Paolo Ruffini published a paper on the theory of equations with his claim that quintics could not be solved by radicals as the title shows: General theory of equations in which it is shown that the algebraic solution of the general equation of degree greater than four is impossible.
• As representative of the "old school" [Malfatti] had long believed that the general quintic equation could be solved algebraically, and had once published a supposed proof of this result.
• In fact he published twenty-two memories on mathematical analysis, geometry, the theory of algebraic equations, mathematical physics, the theory of difference equations, combinatorics and probability.
• These include: Problems and methods of mathematical analysis in the work of Gianfrancesco Malfatti, Contributions of Gianfrancesco Malfatti to combinatorial analysis and to the theory of finite difference equations, The work of Malfatti in the realm of mechanics, The geometrical research of Gianfrancesco Malfatti, Gianfrancesco Malfatti and the theory of algebraic equations, and Gianfrancesco Malfatti and the support problem.

9. Étienne Bézout (1730-1783)
• As we have indicated Bezout is famed for being a writer of textbooks but he is famed also for his work on algebra, in particular on equations.
• His first paper on the theory of equations Sur plusieurs classes d'equations de tous les degres qui admettent une solution algebrique Ⓣ examined how a single equation in a single unknown could be attacked by writing it as two equations in two unknowns.
• It is known that a determinate equation can always be viewed as the result of two equations in two unknowns, when one of the unknowns is eliminated.
• Of course on the face of it this does not help solve the equation but Bezout made the simplifying assumption that one of the two equations was of a particularly simple form.
• For example he considered the case when one of the two equations had only two terms, the term of degree n and a constant term.
• Already this paper had introduced the topic to which Bezout would make his most important contributions, namely methods of elimination to produce from a set of simultaneous equations, a single resultant equation in one of the unknowns.
• He also did important work on the use of determinants in solving equations.
• This appears in a paper Sur le degre des equations resultantes de l'evanouissement des inconnues Ⓣ which he published in 1764.
• As a result of the ideas in this paper for solving systems of simultaneous equations, Sylvester, in 1853, called the determinant of the matrix of coefficients of the equations the Bezoutiant.
• These and further papers published by Bezout in the theory of equations were gathered together in Theorie generale des equations algebraiques Ⓣ which was published in 1779.
• The degree of the final equation resulting from any number of complete equations in the same number of unknowns, and of any degrees, is equal to the product of the degrees of the equations.
• By a complete equation Bezout meant one defined by a polynomial which contains terms of all possible products of the unknowns whose degree does not exceed that of the polynomial.
• nor could he even label his equations with a suffix notation.
• History Topics: Quadratic cubic and quartic equations .

10. Alberto Dou (1915-2009)
• This research involved investigating the application of differential geometry to differential equations.
• In 1955 he was appointed to the Chair of Mathematics at the School of Engineering in Madrid, and in 1957 he won the Chair of Mathematical Analysis III (Differential Equations) at the Universidad Complutense of Madrid.
• Dou's main areas of research were Differential Geometry, the Theory of Elasticity, and the Variational Theory of Partial Differential Equations.
• For example, early in his career he published Rang der ebenen 4-Gewebe Ⓣ in the Journal of the Mathematical Seminar of the University of Hamburg (1955), La representacion simetrica de los cuatritejidos hexagonales Ⓣ (1957), El principio de Saint-Venant en las vigas Ⓣ (1961), Beam with a ring for cross-section, excited by longitudinal and body forces in the Proceedings of the International Conference 'Partial Differential Equations and Continuum Mechanics' held at the University of Wisconsin in Madison (1961), El teorema de unicidad en elasticidad plana Ⓣ (1962), and Sistemas diferenciales ordinarios lineales con coeficientes constantes Ⓣ (1962).
• In order to achieve a degree of unity, to be relatively comprehensive, and to have a reasonable length, this new text directs attention only to the Cauchy problem for a single equation and for systems of equations.
• The content is divided into four main divisions which deal with methods of solution; existence, uniqueness and continuation of solutions; systems of linear equations; and numerical methods.
• Chapter I: First order partial differential equations.
• (A) Semilinear equations: (1) Introduction, (2) Integral surfaces and first integrals, (3) The Cauchy problem; (B) The general equation with two independent variables: (4) Monge curves, (5) The Cauchy problem, (6) The method of the complete integral, (7) The example p2 + q2 + f(x, y) = 0; (C) The equation with more than two independent variables: (8) The Cauchy method, (9) The Hamilton-Jacobi method.
• Chapter II: Introduction to second order equations.
• Typical examples from applied mathematics: (1) The membrane equation, (2) The heat equation, (3) Equations of elliptic type.
• In 1972 he published a text in English, namely Lectures on partial differential equations of first order.
• This book is the result of lectures which the author gave at the Universities of Madrid and Notre Dame (Indiana), and represents the first part of a planned "Introduction to the theory of partial differential equations''.
• He held the Chair of Mathematical Analysis III (Differential Equations) at the Universidad Complutense of Madrid (UCM) from 1957 and, in 1967 he was appointed director UCM's new Department of Functional Equations in the Mathematics Section of the Faculty of Sciences.
• When he had come back to Madrid from San Sebastian in 1977 Dou also returned to his Chair of Mathematical Analysis III (Differential Equations) at the UCM.
• In addition to his research in Differential Geometry, Differential Equations, and the Theory of Elasticity, Dou wrote articles on the foundations of mathematics.

• It was here where she first started studying algebra, number theory and subsequently partial differential equations.
• She became interested in the theory of partial differential equations due to the influence of Petrovsky as well as the book by Hilbert and Courant.
• Being a talented student, the authorities often ignored absences at compulsory lectures while she attended research seminars including the algebra seminars of Kurosh and Delone and the seminar on differential equations headed by Stepanov, Petrovsky, Tikhonov, Vekua and their students and colleagues.
• At the end of her fourth year she organized a youth seminar to study the theory of partial differential equations and persuaded Myshkis, a student of Petrovsky, to go with her to ask Petrovsky to chair the seminar.
• Find the least restrictive conditions on the behaviour of parabolic equations under which the uniqueness theorem holds for the Cauchy problem.
• For hyperbolic equations, construct convergent difference schemes for the Cauchy problem and for initial-boundary problems.
• It was also here that she was strongly influenced to study the equations of mathematical physics.
• In 1949 Olga defended her doctoral dissertation (comparable to an habilitation) which was on the development of finite differences methods for linear and quasilinear hyperbolic systems of partial differential equations, formally supervised by Sobolev though in practice it was Smirnov.
• Her first book published in 1953 called Mixed Problems for a Hyperbolic Equation used the finite difference method to prove theoretical results, mainly the solvability of initial boundary-value problems for general second-order hyperbolic equations.
• As in the previous decade, during the 1960s she continued obtaining results about existence and uniqueness of solutions of linear and quasilinear elliptic, parabolic, and hyperbolic partial differential equations.
• She then studied the equations of elasticity, the Schrodinger equation, the linearized Navier-Stokes equations, and Maxwell's equations.
• The Navier-Stokes equations were of great interest to her and continued to be so for the rest of her life.
• Many papers written jointly by Olga and Nina Ural'tseva were devoted to the investigation of quasilinear elliptic and parabolic equations of the second order.
• At the start of the last century Sergi Bernstein proposed an approach to the study of the classical solvability of boundary-value problems for equations based on a priori estimates for solutions as well as describing conditions that are necessary for such solvability.
• From the mid-1950's Olga and her students made advances in the study of boundary-value problems for quasilinear elliptic and parabolic equations.
• They developed a complete theory for the solvability of boundary-value problems for uniformly parabolic and uniformly elliptic quasilinear second-order equations and of the smoothness of generalized solutions.
• One result gave the solution of Hilbert's 19th problem for one second-order equation.
• When Olga first started to work on the Navier-Stokes equation, she was unaware of the work of Leray and Eberhard Hopf.

12. Patrick Keast (1942-2016)
• Mike Osborne, who came to Edinburgh in July 1963 as Assistant Director of the University Computer Unit, contributed some lectures on the numerical solution of differential equations to Fulton's honours course.
• Finite-difference solutions are considered for the heat conduction equation in one space dimension subject to general boundary conditions involving linear combinations of the function and its space derivative.
• They published a joint paper in 1966 entitled On a boundary-value problem for the equation of heat.
• In the following year, 1967, Keast published his second paper with Ron Mitchell, Finite difference solution of the third boundary problem in elliptic and parabolic equations.
• Finite difference methods (including the Peaceman-Rachford method) are considered for the solution of the third boundary value problem for parabolic and elliptic equations.
• He and Keast wrote the joint paper The stability of difference approximations to a selfadjoint parabolic equation, under derivative boundary conditions which was published in 1968.
• A self-adjoint parabolic equation in one space variable is considered, under boundary conditions which involve the function and its space derivative.
• A type of numerical instability can arise, which is traceable to the boundary conditions, and which is caused by the existence of unbounded solutions of the original differential equation.
• Keast's first single author paper was The third boundary value problem for elliptic equations (1968).
• In [Finite difference solution of the third boundary problem in elliptic and parabolic equations], the author discussed the numerical solution of the heat conduction equation in an open rectangular region, under boundary conditions involving a linear combination of the function and its normal derivative.
• It was shown that the instability which was observed in the difference methods examined, could be traced to the existence of solutions of the differential equation which grew, asymptotically, with time.
• This numerical instability was important in the solution of the heat equation only for large values of the time, and so did not affect calculations which were carried out over a few time steps.
• But, in the numerical solution of elliptic equations by iteration, such asymptotic instability will prevent convergence of the iterative process to the original system of equations.
• It is the purpose of this note to demonstrate this fact, and also to discuss the solution of Laplace's and Poisson's equations, when the Laplacian operator is singular, in a sense to be defined.
• It will be shown that, for certain boundary conditions, the numerical solution of Laplace's equation is best obtained by direct methods, rather than by iterative methods.

13. Ivar Fredholm (1866-1927)
• As was always the case with all the deep mathematical results which Fredholm produced, this result was inspired by mathematical physics, in this case by the heat equation.
• This paper is discussed in detail in [',' D Khavinson and H S Shapiro, The heat equation and analytic continuation : Ivar Fredholm’s first paper, Exposition.
• His 1898 doctoral dissertation involved a study of partial differential equations, the study of which was motivated by an equilibrium problem in elasticity.
• He solved his operator equation in the particular cases which arise in the study of the physical problem in his thesis (and in the paper which appeared in 1900 based on that thesis) while the general case was solved by Fredholm somewhat later and not published until 1908.
• Fredholm is best remembered for his work on integral equations and spectral theory.
• Two years later in Stockholm a lecture about the 'principal solutions' of Roux and their connections with Volterra's equation led to a vivid discussion Finally, after a long silence Fredholm spoke and remarked in his usual slow drawl: in potential theory there is also such an equation.
• In 1900 a preliminary report on his theory of Fredholm integral equations was published as Sur une nouvelle methode pour la resolution du probleme de Dirichlet Ⓣ.
• Volterra had earlier studied some aspects of integral equations but before Fredholm little had been done.
• Of course Riemann, Schwarz, Carl Neumann, and Poincare had all solved problems which now came under Fredholm's general case of an integral equation; this was an indication of how powerful his theory was.
• Hilbert immediately saw the he importance of Fredholm's theory, and during the first quarter of the 20th century the theory of integral equations became a major research topic.
• Fredholm published a fuller version of his theory of integral equations in Sur une classe d'equations fonctionelle Ⓣ which appeared in Acta Mathematica in 1903.
• Hilbert extended Fredholm's work to include a complete eigenvalue theory for the Fredholm integral equation.
• Fredholm's work on integral equations was met with great interest and boosted the morale and self-respect of Swedish mathematicians who so far had been working under the shadow of the continental cultural empires Germany and France.
• Integral equations had now become a new mathematical tool not confined to symmetrical kernels.
• Unlikely as it sounds, he built his first violin from half a coconut, while he also used his talents at building machines to make one to solve differential equations.
• Fredholm received many honours for his mathematical contributions, including the V A Wallmarks Prize for the theory of differential equations in 1903, the Poncelet Prize from the French Academy of Sciences in 1908, and an honorary doctorate from the University of Leipzig in 1909.

14. Li Zhi (1192-1279)
• This was a notation for an equation and, although the work of Li Zhi is the earliest source of the method, it must have been invented before his time.
• Here the numbers which in our notation correspond to the coefficients of the equation are placed above each other so that the coefficient of x is placed above the constant, the coefficient of x2 is placed above the coefficient of x etc.
• Unlike most western algebraists, Li Zhi never explains how to solve equations, but only how to construct them.
• But he does not limit his reflections to equations of degree two or three; for him, the fact that polynomial equations of arbitrarily high degree are involved is of little importance.
• Moreover, he never explains what he understands by an equation, an unknown, a negative number, etc., but only describes the manipulations which should be carried out in specific problems, without worrying about arranging his text in terms of definitions, rules and theorems.
• To solve the above equation Li Zhi would bring the leading coefficient to -1 and then give the solution; in this case 20.
• The type of problem which worried mathematicians in Islamic countries, and in Europe, concerning the solution of cubic, quartic, and higher order equations did not seem to arise in China.
• Li Zhi seems happy with equations of any degree and, although methods to solve equations do not appear explicitly, one has to assume that he used methods similar to those Ruffini and Horner discovered over 600 years later.
• If we examine Li Zhi's solution closely we see a remarkable depth of understanding of equations.
• The problem leads to a quartic equation with a factor x + 16.
• Li Zhi goes through the detailed, and quite hard, argument which leads to the quartic equation .
• The central theme is the construction and formulation of quadratic equations.
• Some of these equations are solved by the "coefficient array method" described above, but some are formulated using the tiao duan or "method of sections".
• This older geometric style method of solving equations was used by Chinese mathematicians before Li Zhi and so the New steps in computation gives historians a unique opportunity to see the new coefficient array method beside the older method of sections.
• This is the quadratic equation we wrote in Li Zhi's coefficient array method above.

15. Dmitrii Matveevich Sintsov (1867-1946)
• During this period he was being advised on research topics by Vasil'ev and, following his advice, he wrote his Master's Thesis The Theory of Connexes in Space in Connection with the Theory of First Order Partial Differential Equations.
• Clebsch constructed the geometry of a ternary connex and applied it to the theory of ordinary differential equations.
• Of course through his many years of research his interests varied but the main areas on which he worked were the theory of conics and applications of this geometrical theory to the solution of differential equations and, perhaps most important of all, the theory of nonholonomic differential geometry.
• These were first published during the years 1927-1940 and include: A generalization of the Enneper-Beltrami formula to systems of integral curves of the Pfaffian equation Pdx + Qdy + Rdz = 0 (1927); Properties of a system of integral curves of Pfaff's equation, Extension of Gauss's theorem to the system of integral curves of the Pfaffian equation Pdx + Qdy + Rdz = 0 (1927); Gaussian curvature, and lines of curvature of the second kind (1928); The geometry of Mongian equations (1929); Curvature of the asymptotic lines (curves with principal tangents) for surfaces that are systems of integral curves of Pfaffian and Mongian equations and complexes (1929); On a property of the geodesic lines of the system of integral curves of Pfaff's equation (1936); Studies in the theory of Pfaffian manifolds (special manifolds of the first and second kind) (1940) and Studies in the theory of Pfaffian manifolds (1940).
• There he studied the geometry of Monge equations and he introduced the important ideas of asymptotic line curvature of the first and second kind.
• In 1903 he published two papers on the functional equation f (x, y) + f (y, z) = f (x, z), now called the 'Sintsov equation,' which are discussed by Detlef Gronau in [',' D Gronau, A remark on Sincov’s functional equation, Notices of the South African Mathematical Society 31 (1) (2000), 1-8.','4].
• But before, it was Moritz Cantor who proposed these equations (there are two equations).
• Cantor quotes these equations as examples of equations in three variables which can be solved by the method of differential calculus due to Niels Henrik Abel.

16. Bryce McLeod (1929-2014)
• Apparently, this gentleman had lost track of what mathematics a 10-year-old would have been exposed to, and he began the first lesson with algebra, completing linear equations in around 15 minutes, and then delving into the quadratic equation.
• But when he returned the next day he was able to solve every quadratic equation his grandfather gave him.
• During the time McLeod was studying for his Oxford B.A., Chaundy taught the courses 'Elementary differential equations and Legendre's functions' and 'Partial differential equations.
• Elliptic equations.
• Parabolic equations' and McLeod became fascinated with the topic.
• The rest of his mathematical career was influenced by the courses and tutorials given by Chaundy on differential equations.
• This year of 1958 also marks the time that his first paper was published, namely On a functional equation which he wrote jointly was T W Chaundy who, as we have already noted, had been his tutor and had inspired him to work in this area.
• He solved problems with consummate skill across an extraordinary range of areas as diverse as fluid mechanics, general relativity, plasma physics, mathematical biology, superconductivity, Painleve equations, coagulation processes, nonlinear diffusion and pantograph equations, among many others.
• The Naylor Prize and Lectureship in Applied Mathematics is awarded to Professor J Bryce McLeod, FRS, of the University of Oxford, in recognition of his profound and versatile lifelong achievement in the analysis of nonlinear differential equations arising in mechanics, physics and biology, and of its lasting influence.
• For example, in 1962 he devised a proof, far ahead of its time, that an infinite system of coagulation - fragmentation equations has non-trivial solutions; in 1971, his seminal paper with Tosio Kato on the asymptotic behaviour of functional differential equations broke completely new ground in what was then a new area; in 1977, with Paul Fife he established that solutions to reaction-diffusion equations converge to travelling waves (this now-classic paper has since been extended, in particular, by McLeod and others to an important integral equation from mathematical neuroscience); in 1979, he devised an ingenious proof that Krasovskii's conjecture concerning the maximum slope of a water wave is false; in the 1980s, his work with Stuart Hastings and others was among the first contributions to the rediscovery in modern times of the Painleve transcendents; in fundamental work with Avner Friedman in 1985 he proved that for reaction-diffusion equations with certain nonlinearities, solutions blow up in finite time and in 1995, with Gero Friesecke, he showed that dynamics provides a mechanism which prevents the solution to a model of phase transformations from generating an infinitely fine microstructure.
• McLeod has written one book, Classical methods in ordinary differential equations.
• The methods include shooting (their most favorite), using estimates to bound the solutions, rewriting differential equations as integral equations (to set up an iteration scheme, and to give a rigorous approach to asymptotic expansions), and rewriting linear ODEs in self-adjoint form.

17. Stefan Bergman (1895-1977)
• This was Erhard Schmidt who had been awarded his doctorate by the University of Gottingen for a thesis on integral equations written under Hilbert's supervision.
• Bergman used the theory of integral equations as developed by Erhard Schmidt and David Hilbert [',' W A Smeaton, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1]:- .
• This led him further to a general theory of integral operators that map arbitrary analytic functions into solutions of various partial differential equations.
• While at Brown University he participated in the Summer School in 1941 Advanced instruction and research in mechanics which resulted in the publications Partial Differential Equations and Fluid dynamics.
• Several years ago Stefan Bergman discovered that essentially the same is true for a vast class of partial differential equations which includes the potential equation as the simplest case.
• Bergman gave explicit formulae which allow a solution of a given differential equation to derive from an arbitrarily chosen analytic function (in some instances from a pair of real functions) and proved that all solutions can be derived in this way.
• They consider a special type of differential equation, yet more general than the potential equation, and build up a system of solutions in close analogy to the procedure followed in the theory of analytic functions.
• In 1953 Bergman and Schiffer published Kernel functions and elliptic differential equations in mathematical physics.
• In this book the authors collect their researches of the last few years on elliptic partial differential equations.
• The second part lays more stress on rigor, and treats fundamental solutions, reduction of boundary value problems to integral equations, orthonormal systems and kernel functions, eigenvalue problems associated with the kernels, variational theory of domain functions, comparison domains, basic existence theorems, and dependence of solutions on the boundary data or on the coefficients of the differential equation.
• The presentation is in an easy flowing style, and the material should prove to be a most useful guide to those interested in the more advanced theory of linear elliptic partial differential equations.
• Bergman published Integral operators in the theory of linear partial differential equations in 1961.
• This book was reviewed by Copson (see [',' E T Copson, Review: Integral Operators in the Theory of Linear Partial Differential Equations by Stefan Bergman, The Mathematical Gazette 46 (357) (1962), 256.','2]) and White (see [',' R von Mises, Review: Quarterly Journal of Applied Mathematics, Science 99 (2561), 81-82.','10]).
• This treatise gives a summary of the author's numerous contributions from 1926 to 1961 to the theory of solutions of linear partial differential equations in two and three real variables by means of integral operators which usually involve analytic functions of one, or sometimes two, complex variables.
• Awards are made every year or two in: 1) the theory of the kernel function and its applications in real and complex analysis; or 2) function-theoretic methods in the theory of partial differential equations of elliptic type with attention to Bergman's operator method.

18. Bruce Kellogg (1930-2012)
• His thesis was Hyperbolic Equations with Multiple Characteristics and he published a paper with the same title in the Transactions of the American Mathematical Society in 1959.
• While working at Westinghouse's Bettis Atomic Power Laboratory, Kellogg published papers such as: (with L C Noderer) Scaled iterations and linear equations (1960); Another alternating-direction-implicit method (1963); Difference equations on a mesh arising from a general triangulation (1964); An alternating direction method for operator equations (1964); and (with J Spanier) On optimal alternating direction parameters for singular matrices (1965).
• Another major theme of his research was the behaviour of solutions to partial differential equations near corners and interfaces.
• His 1976 regularity result (with John Osborn) for the Stokes equations in a convex polygon is still frequently referenced today.
• An alternating direction iteration method is formulated, and convergence is proved, for the solution of certain systems of nonlinear equations.
• D F Mayers writes in a review of On the spectrum of an operator associated with the neutron transport equation (1969):- .
• The results also prove that the transport equation itself has a unique solution for the boundary conditions considered.
• The author determines the behaviour of the solutions of second order elliptic differential equations in two independent variables at points where two interface curves cross, where an interface curve meets the boundary, or where an interface or boundary has a discontinuous tangent.
• The mathematical foundations of the finite element method with applications to partial differential equations (1972) begins:- .
• We consider interface problems for an elliptic partial differential equation in two independent variables.
• Kellogg's own summary to Discontinuous solutions of the linearized, steady state, compressible, viscous, Navier-Stokes equations (1988) is as follows:- .
• The compressible steady state viscous Navier-Stokes equations in two space dimensions are considered.
• The equations are linearised around a given ambient flow field.
• It is shown that the linearised equations are not, in general, elliptic.
• Some boundary value problems for a second-order elliptic partial differential equation in a polygonal domain are considered.
• The highest order terms in the equation are multiplied by a small parameter, leading to a singularly perturbed problem.

19. Niels Abel (1802-1829)
• While in his final year at school, however, Abel had begun working on the solution of quintic equations by radicals.
• In 1823 Abel published papers on functional equations and integrals in a new scientific journal started up by Hansteen.
• In Abel's third paper, Solutions of some problems by means of definite integrals he gave the first solution of an integral equation.
• Abel began working again on quintic equations and, in 1824, he proved the impossibility of solving the general equation of the fifth degree in radicals.
• Geometers have occupied themselves a great deal with the general solution of algebraic equations and several among them have sought to prove the impossibility.
• The second of these explanations does seem the more likely, especially since Gauss had written in his thesis of 1801 that the algebraic solution of an equation was no better than devising a symbol for the root of the equation and then saying that the equation had a root equal to the symbol.
• He had been working again on the algebraic solution of equations, with the aim of solving the problem of which equations were soluble by radicals (the problem which Galois solved a few years later).
• Also after Abel's death unpublished work on the algebraic solution of equations was found.
• In fact in a letter Abel had written to Crelle on 18 October 1828 he gave the theorem [',' M I Rosen, Niels Henrik Abel and the equation of the fifth degree, Amer.
• If every three roots of an irreducible equation of prime degree are related to one another in such a way that one of them may be expressed rationally in terms of the other two, then the equation is soluble in radicals.
• An extract from Abel's On the algebraic resolution of equations (1824) .

• Having introduced the natural numbers, al-Khwarizmi introduces the main topic of this first section of his book, namely the solution of equations.
• His equations are linear or quadratic and are composed of units, roots and squares.
• He first reduces an equation (linear or quadratic) to one of six standard forms: .
• Here "al-jabr" means "completion" and is the process of removing negative terms from an equation.
• The term "al-muqabala" means "balancing" and is the process of reducing positive terms of the same power when they occur on both sides of an equation.
• Al-Khwarizmi then shows how to solve the six standard types of equations.
• For example to solve the equation x2 + 10 x = 39 he writes [',' F Rosen (trs.), Muhammad ibn Musa Al-Khwarizmi : Algebra (London, 1831).','11]:- .
• The question therefore in this type of equation is about as follows: what is the square which combined with ten of its roots will give a sum total of 39? The manner of solving this type of equation is to take one-half of the roots just mentioned.
• in his introductory section al-Khwarizmi uses geometrical figures to explain equations, which surely argues for a familiarity with Book II of Euclid's "Elements".
• Al-Khwarizmi's concept of algebra can now be grasped with greater precision: it concerns the theory of linear and quadratic equations with a single unknown, and the elementary arithmetic of relative binomials and trinomials.
• From its true emergence, algebra can be seen as a theory of equations solved by means of radicals, and of algebraic calculations on related expressions..
• The final part of the book deals with the complicated Islamic rules for inheritance but require little from the earlier algebra beyond solving linear equations.
• The work, described in detail in [',' B van Dalen, Al’Khwarizmi’s astronomical tables revisited : analysis of the equation of time, in From Baghdad to Barcelona (Barcelona, 1996), 195-252.','48], is based in Indian astronomical works [',' Z K Sokolovskaya, The ’pretelescopic’ period of the history of astronomical instruments.
• Al-Khwarizmi and quadratic equations .
• History Topics: Quadratic, cubic and quartic equations .

21. Carlo Miranda (1912-1982)
• His thesis, on singular integral equations of the first and second kind with non-symmetric kernel, and the related question of the integral representation of a square integrable function, was inspired by the research of Tage Gills Torsten Carleman.
• Examples of his work around this time are: Su un problema di Minkowski Ⓣ (1939) which considers the problem of determining a convex surface of given Gaussian curvature; Su alcuni sviluppi in serie procedenti per funzioni non necessariamente ortogonali Ⓣ (1939) which examines expansion theorems in terms of the characteristic solutions of an integral equation whose kernel, although symmetric, involves the characteristic parameter; Nuovi contributi alla teoria delle equazioni integrali lineari con nucleo dipendente dal parametro Ⓣ (1940) which examines the development of the Hilbert-Schmidt theory for a particular type of linear integral equation; and Observations on a theorem of Brouwer (1940) which gave an elementary proof of the equivalence of Brouwer's fixed point theorem and a special case of Kronecker's index theorem.
• Antonio Avantaggiati describes Miranda's mathematical contributions in detail in [',' D Greco (ed.), Methods of Functional Analysis and Theory of Elliptic Equations.
• Proceedings of international Meeting dedicated to the memory of Professor Carlo Miranda (Naples, 1983).','1] and divides these contributions into the following areas: (a) Integral equations, series expansions, summation methods; (b) Harmonic mappings, potential theory, holomorphic functions; (c) Calculus of variations, differential forms, elliptic systems; (d) Numerical analysis; (e) Propagation problems; (f) Differential geometry in the large; (g) General theory for elliptic equations; and (h) Functional transformations.
• Jesus Hernandez writes in a review of [',' D Greco (ed.), Methods of Functional Analysis and Theory of Elliptic Equations.
• Several of these contributions are treated with some detail: results concerning normal families and approximation theory, the equivalence between Brouwer's fixed point theorem and a result for the zeroes of some systems of continuous functions, the Cauchy-Dirichlet problem for the propagation equation, the numerical integration of the Thomas-Fermi equation, integral equations (introducing the notions of pseudofunction and singular eigenvalue), problems of differential geometry "in the large", etc.
• His work on partial differential equations, especially on first order linear systems in dimension greater than 2 (where conformal mapping cannot be used), is very interesting, and the same thing can be said about the integration of exterior differential forms of any degree (establishing for the first time in 1953 the algebraic-topological nature of the index for some elliptic problems).
• The proof of the maximum modulus principle for elliptic equations of order 2m is also remarkable.
• We point out his very special interest in two of the main tools of the "modern" theory of partial differential equations, namely a priori estimates and the application of functional analysis.
• Some attention is paid to his important book on partial differential equations.
• This monograph is essentially a complete and thorough review of various methods that have been introduced in the mathematical literature to prove existence theorems for problems concerning second order partial differential equations of elliptic type, both linear and nonlinear.
• With powerful synthesis and truly wonderful discerning exposition, the author succeeds in this goal by providing students of partial differential equations with a work of fundamental importance.
• Following his sudden death, he was honoured by the Academy of Science Physics and Mathematics of Naples who set up an award in his name for young Italian analysts specialising in the study of elliptic equations.
• An international conference on Methods of functional analysis and theory of elliptic equations was held in his honour in Naples 13-16 September 1982.

• Marchenko's scientific interests generally centre around problems in mathematical analysis, the theory of differential equations, and mathematical physics.
• Also in the 1950s he studied the asymptotic behaviour of the spectral measure and of the spectral function for the Sturm-Liouville equation.
• He is well known for his original results in the spectral theory of differential equations, including the discovery of new methods for the study of the asymptotic behaviour of spectral functions and the convergence expansions in terms of eigenfunctions.
• He also obtained fundamental results in the theory of inverse problems in spectral analysis for the Sturm-Liouville and more general equations.
• With great success, Marchenko applied his methods to the Schrodinger equation.
• Besides the basic results on the structure of the spectrum and the eigenfunction expansion of regular and singular Sturm-Liouville problems, it is in this domain that one-dimensional quantum scattering theory, inverse spectral problems and, of course, the surprising connections of the theory with nonlinear evolution equations first become related.
• The periodic case of the Korteweg-de Vries equation was solved by Marchenko in 1972.
• In addition to the important monographs mentioned above, other major texts written by Marchenko include Nonlinear equations and operator algebras (1986).
• We systematically present a method for solving some physically important nonlinear equations that is based on the replacement of a given equation by an equation of the same form with respect to functions that take values in an arbitrary operator algebra.
• The solution of an operator equation in the form of a travelling wave (a one-soliton solution) is elementary.
• The solutions of the original equation are obtained from the one-soliton operator solutions by bordering them with special finite-dimensional projectors.
• Arbitrariness in the choice of the operator algebra and the bordering projectors allows us to find broad classes of solutions of the Korteweg-de Vries, Kadomtsev-Petviashvili, nonlinear Schrodinger, sine-Gordon, Toda lattice, Langmuir and other equations.
• In 1992 Marchenko's monograph Orthogonal functions of a discrete argument and their application in geophysics was published and in 2005, in collaboration with Evgeni Yakovlevich Khruslov, he wrote Homogenization of partial differential equations.

23. Torsten Carleman (1892-1949)
• One reason was that many of his results, for instance the extension of Holmgren's uniqueness theorem, the analysis of the Schrodinger operator, and the existence theorem for Boltzmann's equation, were two decades ahead of their time and therefore not immediately appreciated.
• As it is often the case with mathematicians who deal with differential or integral equations, Carleman carried a keen interest in the relationship between mathematics and applied sciences.
• Before his professorship in Lund he published about thirty papers, the majority treating of the problems in the theory of integral equations, and the theory of real and complex functions, where he gave extraordinary evidence of originality, penetration and capacity to use various methods of analysis.
• One of them is his fundamental contribution on singular integral equations and applications.
• His first book Singular integral equations with real and symmetric kernel published in 1923 became fundamental.
• Carleman is now remembered for remarkable results in integral equations (1923), quasi-analytic functions (1926), harmonic analysis (1944), trigonometric series (1918-23), approximation of functions (1922-27) and Boltzmann's equation (1944).
• Names such as Carleman inequality, Carleman theorems (Denjoy-Carleman theorem on quasi-analytic classes of functions, Carleman theorem on conditions of well-definedness of moment problems, Carleman theorem on uniform approximation by entire functions, Carleman theorem on approximation of analytic functions by polynomials in the mean), Carleman singularity of orthogonal system, integral equation of Carleman type, Carleman operator, Carleman kernel, Carleman method of reducing an integral equation to a boundary value problem in the theory of analytic functions, Jensen-Carleman formula in complex analysis, Carleman continuum, Carleman linearization or Carleman embedding technique, Carleman polynomials, Carleman estimate in the unique continuation problem for solutions of partial differential equations and Carleman system in the kinetic theory of gas are well-known in mathematics (see [',' Encyclopaedia of Mathematics 2 (Kluwer 1988), 25-26.
• In 1932 Carleman, following an idea of Poincare, showed that a finite dimensional system of nonlinear differential equations d u/dt = V(u), where Vk are polynomials in u, can be embedded in an infinite system of linear differential equations.
• Results on unique continuation for solutions to partial differential equations are important in many areas of applied mathematics, in particular in control theory and inverse problems.
• Carleman lectured at the Sorbonne in 1937 on Boltzmann's equation, which appears in the kinetic theory of gas, and published several papers on this subject.
• Also his last book Mathematical problems of the kinetic theory of gas which deals with the mathematical aspects of the Boltzmann transport equation was published, after his death, in 1957 with some additional material submitted by L Carleson and O Frostman.

24. Sharaf al-Din al-Tusi (about 1135-1213)
• What is in this Treatise on equations by al-Tusi? Basically it is a treatise on cubic equations, but it does not follow the general development that came through al-Karaji's school of algebra.
• it represents an essential contribution to another algebra which aimed to study curves by means of equations, thus inaugurating the beginning of algebraic geometry.
• In the treatise equations of degree at most three are divided into 25 different types.
• First al-Tusi discusses twelve types of equation of degree at most two.
• He then looks at eight types of cubic equation which always have a positive solution, then five types which may have no positive solution.
• We illustrate the method by showing how al-Tusi examined one of the five types of equation which under certain conditions has a solution, namely the equation x3 + a = bx, where a, b are positive.
• Al-Tusi's first comment is that if t is a solution to this equation then t3 + a = bt and, since a > 0, t3 < bt so t < √b.
• Thus the equation bx - x3 = a has a solution if a ≤ 2(b/3)3/2.
• Then Al-Tusi deduces that the equation has a positive root if .
• where D is the discriminant of the equation.
• The paper [',' J P Hogendijk, Sharaf al-Din al-Tusi on the number of positive roots of cubic equations, Historia Math.
• (2) 5 (1) (1995), 39-55.','10] and [',' R Rashed, Resolution des equations numeriques et algebre : Saraf-al-Din al-Tusi, Viete (French), Arch.
• Al-Tusi then went on to give what we would essentially call the Ruffini-Horner method for approximating the root of the cubic equation.
• Although this method had been used by earlier Arabic mathematicians to find approximations for the nth root of an integer, al-Tusi is the first that we know who applied the method to solve general equations of this type.

25. Leonhard Euler (1707-1783)
• The core of his research program was now set in place: number theory; infinitary analysis including its emerging branches, differential equations and the calculus of variations; and rational mechanics.
• Studies of number theory were vital to the foundations of calculus, and special functions and differential equations were essential to rational mechanics, which supplied concrete problems.
• He introduced beta and gamma functions, and integrating factors for differential equations.
• He discovered the Cauchy-Riemann equations in 1777, although d'Alembert had discovered them in 1752 while investigating hydrodynamics.
• As well as investigating double integrals, Euler considered ordinary and partial differential equations in this work.
• Problems in mathematical physics had led Euler to a wide study of differential equations.
• He considered linear equations with constant coefficients, second order differential equations with variable coefficients, power series solutions of differential equations, a method of variation of constants, integrating factors, a method of approximating solutions, and many others.
• When considering vibrating membranes, Euler was led to the Bessel equation which he solved by introducing Bessel functions.
• Euler here also begins developing the kinematics and dynamics of rigid bodies, introducing in part the differential equations for their motion.
• He published a number of major pieces of work through the 1750s setting up the main formulae for the topic, the continuity equation, the Laplace velocity potential equation, and the Euler equations for the motion of an inviscid incompressible fluid.
• However sublime are the researches on fluids which we owe to Messrs Bernoulli, Clairaut and d'Alembert, they flow so naturally from my two general formulae that one cannot sufficiently admire this accord of their profound meditations with the simplicity of the principles from which I have drawn my two equations ..
• History Topics: Quadratic, cubic and quartic equations .
• History Topics: Pell's equation .

26. Theodor Anghelu (1882-1964)
• Theodor Angheluță made important contributions to Function Theory, to Differential and Integral Equations, and to Functional and Algebraic Equations.
• A special kind of functional equation is today named after him, namely the 'Angheluță type functional equation'.
• Determination of projective transformations which leave invariant a second degree equation (Romanian) (1937) - Angheluță determines the projective transformations which convert a given quadratic equation into a given second order equation; .
• Discussion of the reality of the roots of equations of the third and fourth degree with real coefficients (Romanian) (1938) - Systematic specification of reality conditions and intervals for the roots of equations of the third and fourth degree; .
• Circuit transformations characterized by a functional equation (Romanian) (1946); .
• On a functional equation (Romanian) (1959); .
• Remarks concerning Poisson's functional equation (Romanian) (1959); .
• The functional equation of a translation (Romanian) (1959) - proves results by J Aczel in a simpler way.
• On a functional equation with three unknown functions (Romanian) (1960); .
• A functional equation for the sine and another for a hyperbolic sine (Romanian) (1961) - gives simpler proofs of results already known; .
• The functional equation of the logarithm (Romanian) (1961) - gives simpler proofs of results already known; .
• About a functional equation (Romanian) (1962) - gives simpler proofs of results already known.

27. Semyon Aranovich Gershgorin (1901-1933)
• The papers he published at this time are (all in Russian): Instrument for the integration of the Laplace equation (1925); On a method of integration of ordinary differential equations (1925); On the description of an instrument for the integration of the Laplace equation (1926); and On mechanisms for the construction of functions of a complex variable (1926).
• He became Professor at the Institute of Mechanical Engineering in Leningrad in 1930, and from 1930 he worked in the Leningrad Mechanical Engineering Institute on algebra, theory of functions of complex variables, numerical methods and differential equations.
• These were on the theory of elasticity, the theory of vibrations, the theory of mechanisms, methods of approximate numerical integration of differential equations and on other areas of mechanics and applied mathematics.
• Gershgorin proposed an original and intricate mechanism for solving the Laplace equation, and he described such a device in detail in 'Instrument for the integration of the Laplace equation' (1925).
• In 1929 Gershgorin published On electrical nets for approximate solution of the differential equation of Laplace (Russian) in which he gave a method for finding approximate solutions to partial differential equations by constructing a model based on networks of electrical components.
• In the following year he published Fehlerabschatzung fur das Differenzverfahren zur Losung partieller Differentialgleichungen Ⓣ in which he made a careful analysis of the convergence of finite-difference approximation methods for solving the Laplace equation.
• In this paper we present a method of conformal mapping of a given (finite or infinite) connected domain onto a disk, which is based on reducing the problem to a Fredholm integral equation.
• L Lichtenstein [in 'Zur Theorie der konformen Abbildung: Konforme Abbildung nicht-analytischer, singularitatenfreier Flachenstucke auf ebene Gebiete' Ⓣ(1916)] had reduced that important problem to the solution of a Fredholm integral equation.
• Independently of Lichtenstein, Gershgorin utilised Nystrom's method and reduced that conformal transformation problem to the same Fredholm integral equation.
• Later, A M Banin solved the Lichtenstein-Gershgorin integral equation approximately, by reducing it to a finite system of linear differential equations.

• He reached an understanding of the number systems and solving equations which was not to be achieved in Europe for several centuries.
• Bhaskaracharya studied Pell's equation px2 + 1 = y2 for p = 8, 11, 32, 61 and 67.
• An example from Chapter 12 on the kuttaka method of solving indeterminate equations is the following:- .
• The topics are: positive and negative numbers; zero; the unknown; surds; the kuttaka; indeterminate quadratic equations; simple equations; quadratic equations; equations with more than one unknown; quadratic equations with more than one unknown; operations with products of several unknowns; and the author and his work.
• Equations leading to more than one solution are given by Bhaskaracharya:- .
• The kuttaka method to solve indeterminate equations is applied to equations with three unknowns.
• The problem is to find integer solutions to an equation of the form ax + by + cz = d.
• Pell's equation .
• History Topics: Pell's equation .

29. Edward Lorenz (1917-2008)
• The paper A generalization of the Dirac equations appeared in the Proceeding of the National Academy of Sciences in 1941.
• in 1948 after submitting the dissertation A Method of Applying the Hydrodynamic and Thermodynamic Equations to Atmospheric Models.
• A generalized vorticity equation for a two-dimensional spherical earth is obtained by eliminating pressure from the equations of horizontal motion including friction.
• The generalized vorticity equation is satisfied by formal infinite series representing the density and wind fields.
• An approximate differential equation is presented, relating the change in speed of the zonal westerly winds to the contemporary zonal wind-speed and the meridional flow of absolute angular momentum.
• This equation is tested statistically by means of values of the momentum flow and the zonal wind-speed, computed with the aid of the geostrophic-wind approximation, from pressure and height data extracted from analyzed northern-hemisphere maps.
• He was using a computer to investigate models of the atmosphere which he had devised involving twelve differential equations.
• Finite systems of deterministic ordinary nonlinear differential equations may be designed to represent forced dissipative hydrodynamic flow.
• Solutions of these equations can be identified with trajectories in phase space.
• The set of equations and the attractors described by this set of equations are now called the 'Lorenz equations' and 'Lorenz attractors', respectively.
• Another account of aperiodic behaviour in ordinary differential equations, and difference equations, in which Lorenz describes how he arrived, starting from the description of convection in meteorology, at the Lorenz equations is contained in his paper On the prevalence of aperiodicity in simple systems delivered at the Biennial Seminar of the Canadian Mathematical Congress in Calgary, Canada, in 1978.

• The important innovation which is incorporated in most of these problems is that they reduce to a cubic equation which Wang solves numerically.
• We do not know of any earlier Chinese work on cubic equations.
• Of course one has to understand that when we say that the text is concerned with cubic equations, we do not see expressions with x, x2 and x3 in them.
• Rather the equations are expressed in words and Wang thinks in a geometrical way.
• For example where we might say "Let the height be x" and then produce an equation in x, Wang writes:- .
• He then goes on to set up a cubic equation for the height.
• when he is about to set up a cubic equation for the depth.
• In setting up cubic equations Wang Xiaotong utilised a rule which is the same as the "tian yuan".
• Data given for the work done by the workers allows the volume to be calculated, and a cubic equation is arrived at for x.
• To be able to solve this problem Wang has not only to be able to set up a cubic equation and solve it, but he also needs to know a formula for the volume of his dyke with trapezoidal ends and varying cross-section.
• Wang calls a the unknown and finds a cubic equation in terms of a.
• Writing x for the unknown a, we have the cubic equation .
• Try to set up the necessary equations in these two cases in a similar way to our solution to Problem 15 above.
• Not only did Wang's work influence later Chinese mathematicians, but it is said that it was his ideas on cubic equations which Fibonacci learnt, probably first transmitted into the Islamic/Arabic world, and then brought to Europe.

31. Lazarus Fuchs (1833-1902)
• It was during this period that he did outstanding work on homogeneous linear differential equations with variable coefficients which was published in the important 40-page paper Zur Theorie der linearen Differentialgleichungen mit veranderlichen Coefficienten Ⓣ which appeared in Crelle's Journal in 1866.
• Fuchs worked on differential equations and the theory of functions.
• Fuchs's mathematical papers are very pleasant to read and free from that tendency to heaviness which is apt to belong to memoirs on differential equations.
• Fuchs was a gifted analyst whose works form a bridge between the fundamental researches of Cauchy, Riemann, Abel, and Gauss and the modern theory of differential equations discovered by Poincare, Painleve, and Emile Picard.
• In 1865 Fuchs studied nth order linear ordinary differential equations with complex functions as coefficients.
• Fuchs enriched the theory of linear differential equations with fundamental results.
• He discussed problems of the following kind: What conditions must be placed on the coefficients of a differential equation so that all solutions have prescribed properties (e.g.
• This led him (1865, 1866) to introduce an important class of linear differential equations (and systems) in the complex domain with analytic coefficients, a class which today bears his name (Fuchsian equations, equations of the Fuchsian class).
• He succeeded in characterising those differential equations the solutions of which have no essential singularity in the extended complex plane.
• Fuchs later also studied non-linear differential equations and moveable singularities.
• In a series of papers (1880-81) Fuchs studied functions obtained by inverting the integrals of solutions to a second-order linear differential equation in a manner generalising Jacobi's inversion problem.
• With these and other functions that I have called zeta Fuchsian, one can solve: (1) All linear differential equations with rational coefficients that have three singularities only, two finite and one infinite.
• (2) All second order equations with rational coefficients.
• (3) A large number of equations of various orders with rational coefficients.
• Fuchs also investigated how to find the matrix connecting two systems of solutions of differential equations near two different points.
• A survey of Fuchs work appears in [',' J J Gray, Fuchs and the Theory of Differential Equations, Bull.
• [Fuchs'] work can profitably be seen as an attempt to impose upon the inchoate world of differential equations the conceptual order of the emerging theory of complex functions.
• As well as being the architect of the rigorous modern theory of linear equations, he raised many questions which were taken up by his contemporaries and provided an interesting battleground for the schools of invariant theory and transformation group theory.
• After discussing the concepts named for Fuchs, Gray writes [',' J J Gray, Fuchs and the Theory of Differential Equations, Bull.

32. Tartaglia (1500-1557)
• The first person known to have solved cubic equations algebraically was del Ferro but he told nobody of his achievement.
• For mathematicians of this time there was more than one type of cubic equation and Fior had only been shown by del Ferro how to solve one type, namely 'unknowns and cubes equal to numbers' or (in modern notation) x3 + ax = b.
• As negative numbers were not used this led to a number of other cases, even for equations without a square term.
• In fact Tartaglia had also discovered how to solve one type of cubic equation since his friend Zuanne da Coi had set two problems which had led Tartaglia to a general solution of a different type from that which Fior could solve, namely 'squares and cubes equal to numbers' or (in modern notation) x3 + ax2 = b.
• As public lecturer of mathematics at the Piatti Foundation in Milan, he was aware of the problem of solving cubic equations, but, until the contest, he had taken Pacioli at his word and assumed that, as Pacioli stated in the Suma published in 1494, solutions were impossible.
• To Tartaglia's dismay, the governor was temporarily absent from Milan but Cardan attended to his guest's every need and soon the conversation turned to the problem of cubic equations.
• Based on Tartaglia's formula, Cardan and Ferrari, his assistant, made remarkable progress finding proofs of all cases of the cubic and, even more impressively, solving the quartic equation.
• Cardan and Ferrari travelled to Bologna in 1543 and learnt from della Nave that it had been del Ferro, not Tartaglia, who had been the first to solve the cubic equation.
• In 1545 Cardan published Artis magnae sive de regulis algebraicis liber unus, or Ars magna as it is more commonly known, which contained solutions to both the cubic and quartic equations and all of the additional work he had completed on Tartaglia's formula.
• For all the brilliance of his discovery of the solution to the cubic equation problem, Tartaglia was still a relatively poor mathematics teacher in Venice.
• Ferrari clearly understood the cubic and quartic equations more thoroughly, and Tartaglia decided that he would leave Milan that night and thus leave the contest unresolved.
• Fairly early in his career, before he became involved in the arguments about the cubic equation, he wrote Nova Scientia (1537) on the application of mathematics to artillery fire.
• History Topics: Quadratic, cubic and quartic equations .

33. Bill Morton (1930-)
• A discussion on numerical analysis of partial differential equations which he published in 1971 gives both a Culham and a University of Reading address for Morton.
• Of all the partial differential equations which are solved numerically, those arising from fluid flow problems are certainly among the most important.
• There is, however, a more pertinent reason for singling out this application area in discussing the numerical analysis of partial differential equations.
• Each particular field has its own complicating difficulties and the equations necessary to describe physically interesting phenomena are often formidable.
• It would therefore be inappropriate to work here with complete systems of realistic equations: instead it will be our aim to bring out some of the important points common to the whole class of fluid flow problems by using in each case the simplest model equations adequate for our purpose.
• We should mention two important books he published: (with David F Mayers) Numerical Solution of Partial Differential Equations: an introduction (1994, 2nd edition 2005); and Numerical Solution of Convection-Diffusion Problems (1996).
• This book is a solid introduction to numerical methods for partial differential equations.
• The book includes parabolic, hyperbolic, and elliptic equations, each section starting with an analysis of the behaviour of solutions of the partial differential equations.
• A very desirable feature of the book is that it goes beyond the usual investigation of the heat equation, the wave equation, and Poisson's equation.
• Professor Keith William (Bill) Morton of the University of Oxford in recognition of his seminal contributions to the field of numerical analysis of partial differential equations and its applications and for services to his discipline.
• The London Mathematical Society is proud to honour a mathematician who has changed the way we look at the numerical analysis of partial differential equations through his world-leading research results, his vision and his dynamic leadership qualities.
• He gave the lecture Evolution Operators and Numerical Modelling of Hyperbolic Equations in the Mathematical Institute, Oxford.

34. Peter Lax (1926-)
• He received his PhD in 1949, also from New York University, for his thesis Nonlinear System of Hyperbolic Partial Differential Equations in Two Independent Variables.
• She was awarded a PhD in 1955 for her thesis Cauchy's Problem for a Partial Differential Equation with Real Multiple Characteristics.
• for his groundbreaking contributions to the theory and application of partial differential equations and to the computation of their solutions.
• The equations that arise in such fields as aerodynamics, meteorology and elasticity are nonlinear and much more complex: their solutions can develop singularities.
• In the 1950s and 1960s, Lax laid the foundations for the modern theory of nonlinear equations of this type (hyperbolic systems).
• Inspired by Richtmyer, Lax established with this theorem the conditions under which a numerical implementation gives a valid approximation to the solution of a differential equation.
• Lax became fascinated by these mysterious solutions and found a unifying concept for understanding them, rewriting the equations in terms of what are now called "Lax pairs".
• This phenomenon occurs not only for fluids, but also, for instance, in atomic physics (Schrodinger equation).
• Their work also turned out to be important in fields of mathematics apparently very distant from differential equations, such as number theory.
• In this monograph, written more than twenty years ago, we based our scattering theory on the wave equation rather than the Schrodinger equation.
• Following up on a hint in Gelfand's address to the 1962 Stockholm International Congress, they showed that the Lax-Phillips scattering theory, applied to the wave equation appropriate to hyperbolic space, is a natural tool in the theory of automorphic functions.
• Yet during the past five decades there has been an unprecedented outburst of new ideas about how to solve linear equations, carry out least square procedures, tackle systems of linear inequalities, and find eigenvalues of matrices.

35. Karl Gräffe (1799-1873)
• Graffe is best remembered for his "root-squaring" method of numerical solution of algebraic equations, developed to answer a prize question posed by the Berlin Academy of Sciences.
• This was not his first numerical work on equations for he had published Beweis eines Satzes aus der Theorie der numerischen Gleichungen Ⓣ in Crelle's Journal in 1833.
• Here, however, the prize decision would not have been made until the year 1838 and, on the other hand, the author flatters himself that his method for calculating the roots of numerical equations deserves to be considered even if other methods should lead more quickly to the result.
• The Preface continues, explaining that he also presents previous attempts by other authors at giving methods to calculate the imaginary roots of an equation.
• Algebraic equations are very often the subject of mathematical research, partly because of the remarkable relationships they offer and partly because of their versatile use.
• Perhaps it is also the fact that for the general solution of equations that exceed the 4th degree, insuperable obstacles seem to stand in the way, which gives a peculiar charm to these investigations, which almost every mathematician is trying to use his powers to consider.
• The process can be applied recursively obtaining equations whose roots are the fourth powers of the original roots, then the eighth powers etc.
• The law by which the new equations are constructed is exceedingly simple.
• If, for example, the coefficient of the fourth term of the given equation is c3, then the corresponding coefficient of the first transformed equation is c32 - 2c2c4 + 2c1c5 - 2c6.
• justifying Graffe's principle and perfecting his method for finding the imaginary roots of an equation.
• As presented by Graffe, the method is only applicable to the case where all the roots of the original equation are distinct but later improvements did away with this condition.
• Lobachevsky, however, only seems to be thinking of the "root squaring" method as a way to calculate the largest root, not as a method for calculating all the roots of an equation.

36. Pierre-Louis Lions (1956-)
• Lions has made some of the most important contributions to the theory of nonlinear partial differential equations through the 1980s and 1990s.
• Keep in mind that there is in truth no central core theory of nonlinear partial differential equations, nor can there be.
• The sources of partial differential equations are so many - physical, probalistic, geometric etc.
• - that the subject is a confederation of diverse subareas, each studying different phenomena for different nonlinear partial differential equation by utterly different methods.
• 70 (2) (1996), 125-135.','3] is his work on "viscosity solutions" for nonlinear partial differential equations.
• The method was first introduced by Lions in joint work with M G Crandall in 1983 in which they studied Hamilton-Jacobi equations.
• Lions and others have since applied the method to a wide class of partial differential equations, the so-called "fully nonlinear second order degenerate elliptic partial differential equations." The problem that arises is decribed in [',' J Lindenstrauss, L C Evans, A Douady, A Shalev and N Pippenger, Fields Medals and Nevanlinna Prize presented at ICM-94 in Zurich, Notices Amer.
• such nonlinear partial differential equation simply do not have smooth or even C1 solutions existing after short times.
• Another equally innovative piece of work by Lions was his work on the Boltzmann equation and other kinetic equations.
• The Boltzmann equation keeps track of interactions between colliding particles, not individually but in terms of a density.
• There are many nonlinear PDEs that are Euler equations for variational problems.
• The first step in solving such equations by the variational method is to show that the extremum is attained.

37. Pietro Abbati Marescotti (1768-1842)
• He published little in the way of research but made many changes to the teaching of mathematics in the University of Modena, introducing the theory of equations as well as analytic mechanics following Lagrange's development of the subject.
• 467-486, in Mathematical works of Paolo Ruffini, edited by E Bortolotti, Rome 1953); Reflections of P Abbati Marescotti of Modena on the method of J-L Lagrange for the solution of numerical equations, Modena 1805; On the computation of rational functions of the roots of any algebraic equation of the form f (x', x'', x''', ..
• degli atti della Societa italiana delle scienze residente in Modena Ⓣ] discusses a problem of probability and specifies the meaning that is to be assigned to the expressions used by Daniel Bernoulli and Joseph-Louis Lagrange in some problems of expectation; all of the other memoirs relate to the theory of algebraic equations.
• Of particular importance is the first one, where Marescotti gives the first correct proof of the algebraic insolubility of general equations of degree greater than five, after having discovered that the proof given by Paolo Ruffini was correct for equations of the fifth degree, but not for those of higher degree.
• Having acknowledged the correct critique Paolo Ruffini (On the insolvability of general algebraic equations of degree greater than four, in Memoirs of mathematics and physics of the Italian society of science, X, 2 (1803), p.
• The letter from Abbati to Ruffini in which he extended Ruffini's proof that quintic equations were not, in general, soluble by radicals was written from Modena and dated 30 September 1802.
• These discuss an interesting number of different ideas in the theory of Diophantine equations, on prime numbers, and particularly on algebraic equations.
• For example, they discussed the relation between the roots of an equation and its coefficients, the number of imaginary roots that an equation possesses, particularly discussing the results of Pietro Paoli.
• Abbati and Ruffini also discussed results concerning permutations of the roots of algebraic equations of degree 4 and also of algebraic equation of degree 5 and above.

• Diophantus, often known as the 'father of algebra', is best known for his Arithmetica, a work on the solution of algebraic equations and on the theory of numbers.
• The Arithmetica is a collection of 130 problems giving numerical solutions of determinate equations (those with a unique solution), and indeterminate equations.
• The work considers the solution of many problems concerning linear and quadratic equations, but considers only positive rational solutions to these problems.
• Equations which would lead to solutions which are negative or irrational square roots, Diophantus considers as useless.
• To give one specific example, he calls the equation 4 = 4x + 20 'absurd' because it would lead to a meaningless answer.
• In other words how could a problem lead to the solution -4 books? There is no evidence to suggest that Diophantus realised that a quadratic equation could have two solutions.
• Diophantus looked at three types of quadratic equations ax2 + bx = c, ax2 = bx + c and ax2 + c = bx.
• He solved problems such as pairs of simultaneous quadratic equations.
• Diophantus would solve this by creating a single quadratic equation in x.
• The symbolism that Diophantus introduced for the first time, and undoubtedly devised himself, provided a short and readily comprehensible means of expressing an equation..
• We began this article with the remark that Diophantus is often regarded as the 'father of algebra' but there is no doubt that many of the methods for solving linear and quadratic equations go back to Babylonian mathematics.
• History Topics: Pell's equation .

• Solution of Dirichlet's problem for an equation of elliptic type (Russian) was published in 1959 and Classes of domains and imbedding theorems for function spaces (Russian) in 1960.
• He published the two papers Some estimates of solutions of second-order elliptic equations (Russian) and p-conductivity and theorems on imbedding certain functional spaces into a C-space (Russian) in 1961, and then four further papers in 1962, the year in which he was awarded his Candidate degree (equivalent to a doctorate) from Moscow State University.
• The Dirichlet problem for an arbitrary order elliptic equation in a domain with a cut off tubular neighbourhood of a smooth closed submanifold is considered in the second chapter.
• The fourth chapter deals with asymptotic expansions of solutions to a quasilinear equation of the second order.
• In 1997 (with Vladimir Kozlov) Maz'ya published Theory of a higher-order Sturm-Liouville equation which Eastham summarises by writing that:- .
• the authors have identified a special type of higher-order analogue of the hyperbolic Sturm-Liouville equation and they have developed a coherent theory based on the Green's function.
• One year later, in 1999, Maz'ya, together with Vladimir Kozlov, published Differential equations with operator coefficients with applications to boundary value problems for partial differential equations.
• All the proofs are complete and rely on undergraduate university courses on real and complex analysis and some basic facts of functional analysis and of the theory of partial differential equations.
• For example we list a few recent works without detailing the co-authors: Spectral problems associated with corner singularities of solutions to elliptic equations (2000); Asymptotic theory of elliptic boundary value problems in singularly perturbed domains (2000); Spectral problems associated with corner singularities of solutions to elliptic equations (2001); and Linear water waves (2002).
• In addition the American Mathematical Society published Perspectives in Partial Differential Equations, Harmonic Analysis and Applications: A Volume in Honor of Vladimir G Maz'ya's 70th Birthday in their Proceedings of Symposia in Pure Mathematics series.
• in recognition of his contributions to the theory of differential equations.

40. Yaroslav Borisovich Lopatynsky (1906-1981)
• His research interests then moved towards differential equations with his first paper on this topic Solution of the equation y ' = f (x, y) published in 1939, proving a general existence theorem.
• He continued to undertake research on differential equations, but his interests now included differential operators.
• The author studies linear (partial) differential equations from a formal algebraic point of view.
• His treatment of this special case of the algebraic theory of algebraic differential equations yields a well-rounded ideal theory of linear differential operators; in many respects it differs essentially from the treatment due to Ritt (for instance, ideals and sums of integral manifolds are defined differently).
• In 1945 Lopatynsky moved to Lvov where he was appointed to the chair of differential equations at Lvov University.
• His seminar on differential equations at Lvov University attracted many mathematicians, both young men beginning their research activity and established researchers who found inspiration in the seminar.
• Lopatynsky's research continued to impress as he continued to prove major results in the theory of systems of linear differential equations of the elliptic type.
• In 1966 he became head of the partial differential equations Section of the Institute of Applied Mathematics and Mechanics of the Academy of Sciences of the Ukraine in Donetsk.
• He was also appointed as Chairman of the Department of Differential Equations at Donetsk University.
• Lopatynsky's contributions to the theory of differential equations are particularly important, with important contributions to the theory of linear and nonlinear partial differential equations.
• He worked on the general theory of boundary value problems for linear systems of partial differential equations of elliptic type, finding general methods of solving boundary value problems.
• he continued his studies of general boundary problems in differential equations using topological methods.
• Recently he has obtained important results on solvability of the Cauchy problem for operator equations in Banach space and also on "almost everywhere" solvability of general linear and nonlinear boundary problems.
• He also obtained some basic results in the solvability of the Cauchy problem for operator equations in Banach spaces.
• In 1980 Lopatynsky published an important book Introduction to the Contemporary Theory of Partial Differential Equations.
• This book makes the reader familiar with the basic notions and facts of algebra, topology, and functional analysis, and gives a general idea how to apply these notions to the theory of differential equations.
• The book contains eight chapters: Sets; Basic algebraic notions; Algebraic equations; Topology; Differentiation and integration; Special linear spaces which are related to Euclidean spaces; Manifolds; and Elements of algebraic topology.
• His next book, published in 1984 three years after his death, was entitled Ordinary differential equations.
• We consider the basic methods of solving differential equations and methods of qualitative investigation of these solutions.
• We emphasize the relation of the theory of differential equations to other areas of mathematics.
• Finally let us mention that the Second International Conference for young mathematicians on Differential Equations and Applications held in November 2008 at the Donetsk National University was dedicated to Ya B Lopatinskii.
• The conference is named after an outstanding mathematician, talented pedagogue and organiser, Academician of National Academy of Sciences of Ukraine Yaroslav Borisovich Lopatinskii who was a founder of both the Department of Differential Equations in Donetsk National University and the Department of Partial Differential Equations in the Institute of Applied Mathematics and Mechanics of National Academy of Sciences of Ukraine.
• The conference is the continuation of the Conference on Differential Equations and Applications dedicated to the centenarian jubilee of Ya B Lopatinskii held in December 2006.

41. Paolo Ruffini (1765-1822)
• On the other hand it gave him the chance to work on what was one of the most original of projects, namely to prove that the quintic equation cannot be solved by radicals.
• To solve a polynomial equation by radicals meant finding a formula for its roots in terms of the coefficients so that the formula only involves the operations of addition, subtraction, multiplication, division and taking roots.
• Quadratic equations (of degree 2) had been known to be soluble by radicals from the time of the Babylonians.
• The cubic equation had been solved by radicals by del Ferro, Tartaglia and Cardan.
• Certainly no mathematician has published such a claim and even Lagrange in his famous paper Reflections on the resolution of algebraic equations says he will return to the question of the solution of the quintic and, clearly, he still hoped to solve it by radicals.
• In 1799 Ruffini published a book on the theory of equations with his claim that quintics could not be solved by radicals as the title shows: General theory of equations in which it is shown that the algebraic solution of the general equation of degree greater than four is impossible.
• The algebraic solution of general equations of degree greater than four is always impossible.
• In writing this book, I had principally in mind to give a proof of the impossibility of solving equations of degree higher than four.
• and recommend greatly the most important theorem which excludes the possibility of solving equations of degree greater than four.
• your memoir on the general resolution of equations is a work which has always seemed to me worthy of the attention of mathematicians and which, in my judgement, proves completely the impossibility of solving algebraically equations of higher than the fourth degree.

42. Edward Ince (1891-1941)
• Ince's research was mainly on differential equations.
• Emile Mathieu discovered the Mathieu functions, which are special cases of hypergeometric functions, in 1868 while solving the wave equation for an elliptical membrane moving through a fluid.
• By the use of convergent infinite determinants and continued fractions, with asymptotic formulae for large values, he succeeded in making computations practicable and after eight years' devotion to this task he published in 1932 tables of eigenvalues for Mathieu's equation, and zeros of Mathieu functions.
• These tables were useful not only in the problems originally envisaged but also in more recent investigations such as quantum-mechanical problems leading to Mathieu's equation.
• Ince published a major text Ordinary Differential Equations (Longmans, Green and Co., London, 1926).
• He contributed Integration of Ordinary Differential Equations and set out his aims in the Preface dated May 1939:- .
• The object of this book is to provide in a compact form an account of the methods of integrating explicitly the commoner types of ordinary differential equation, and in particular those equations that arise from problems in geometry and applied mathematics.
• With this qualification, it will be found to contain all the material needed by students in our Universities who do not specialize in differential equations, as well as by students of mathematical physics and technology.
• A C Aitken and D E Rutherford wrote the Preface to the second edition of Integration of Ordinary Differential Equations of April 1943: .
• The nucleus of an integral equation for one of the periodic Lame functions is expanded in series of products of the characteristic functions ..
• One further paper, Simultaneous linear partial differential equations of the second order, was edited by Erdelyi after Ince's death and published in the Proceedings of the Royal Society of Edinburgh in 1942.

43. Jean Chazy (1882-1955)
• The research he undertook for his doctorate involved the study of differential equations, in particular looking at the methods used by Paul Painleve to solve differential equations that Henri Poincare and Emile Picard had failed to solve.
• Chazy published several short papers while undertaking research, for instance Sur les equations differentielles dont l'integrale generale est uniforme et admet des singularites essentielles mobiles Ⓣ (1909), Sur les equations differentielles dont l'integrale generale possede une coupure essentielle mobile Ⓣ (1910) and Sur une equations differentielle du premier ordre et du premier degre Ⓣ (1911).
• He was awarded his doctorate in 1911 for his thesis Sur les equations differentielles du troisieme ordre et d'ordre superieur dont l'integrale generale a ses points critiques fixes Ⓣ which he defended at the Sorbonne on 22 December 1910.
• In his thesis he was able to extend results obtained by Painleve for differential equations of degree two to equations of degree three and higher.
• The topic posed was: Improve the theory of differential algebraic equations of the second order and third order whose general integral is uniform.
• Having done brilliant work on differential equations, Chazy's interests now turned towards the theory of relativity.
• Chazy's first publication on the subject was Sur les fonctions arbitraires figurant dans le ds2 de la gravitation einsteinienne 2 of Einstein’s gravitation equation',3785)">Ⓣ which appeared in 1921.
• It discusses the principles of relativity, the equations of gravitation, the determination of ds2, Schwarzschild equations of motion, the n-body problem and finally cosmogonic hypotheses related to the ds2 of the universe.
• (8) The ten differential equations of gravitation; .
• (10) The Laplace equation and the Poisson equation.
• Approximate equations of motion; .
• Equations canoniques et variation des constantes Ⓣ.

44. Gamal Ismail (1950-)
• She continued to study for a Master of Science Degree and for this degree she wrote the thesis Numerical treatment of systems of linear equations which she submitted to Ain Shams University in February 1976 as partial fulfilment of the requirements for the degree.
• The first chapter is considered as fundamental for solving sets of linear simultaneous equations.
• First of all, today nearly every linear problem in applied mathematics - as a boundary value problem for a linear ordinary or partial differential equation is reduced by appropriate techniques to a system of linear equations, especially when electronic computers are to be employed for its solution.
• There are several different methods for the solution of sets of equations, the method used depending on the calculating aids available, the type of equations to be solved and the accuracy required in the solution.
• In general, there are two type of numerical techniques for solving simultaneous linear equations: direct methods, which are finite, and indirect methods which are infinite.
• She continued to undertake research for a doctorate advised by Abbas I A Karim and in 1983 they published the joint paper The stability of multistep formulae for solving differential equations.
• The authors give the following Abstract [',' A I A Karim and G A Ismail, The stability of multistep formulae for solving differential equations, Internat.
• By the numerical treatment of differential equations, the question of stability is still important.
• Among these methods are: determination of the characteristic roots, graphical method, Hermitian form obtained from the characteristic equation or from the multi-step formula, application of Newton's theorem and using Sturm's theorem.
• in 1985 for her thesis Accuracy of the multi-step methods for solving differential equations.
• Further papers by Ismail followed: A new higher order effective P-C methods for stiff systems (1998); Stability of nonequidistant variable order multistep methods for stiff systems (2000); A numerical technique for the 3-D Poisson equation (2003), Efficient numerical solution of 3D incompressible viscous Navier-Stokes equations (2004) and A new approach to construct linear multistep formulae for solving stiff ODEs (2005).

45. Hans Lewy (1904-1988)
• In this paper criteria are given for determining conditions which guarantee the stability of numerical solutions of certain classes of differential equations.
• he published a series of fundamental papers on partial differential equations and the calculus of variations.
• He solved completely the initial value problem for general non-linear hyperbolic equations in two independent variables.
• On the basis of this, and using the daring idea of converting an elliptic equation into a hyperbolic one by penetrating into the complex domain, he developed a new proof of the analyticity of solutions of analytic elliptic equations in two independent variables, one which far exceeded the known proof in its elegance and simplicity.
• He proved the well-posedness of the initial value problem for wave equations in what is now called Sobolev spaces two decades before these spaces became a common tool for specialists.
• Nirenberg [',' L Nirenberg, Comments on some of Hans Lewy’s work, in D Kinderlehrer (ed.), Hans Lewy Selecta (Boston, MA, 2002).','6] lists Lewy's mathematical papers under the following topics: (i) partial differential equations involving existence and regularity theory for elliptic and hyperbolic equations, geometric applications, approximation of solutions; (ii) existence and regularity of variational problems, free boundary problems, theory of minimal surfaces; (iii) partial differential equations connected with several complex variables; (iv) partial differential equations connected with water waves and fluid dynamics; (v) offbeat properties of solutions of partial differential equations.
• Among the first papers he published after emigrating to the United States were A priori limitations for solutions of Monge-Ampere equations (two papers, the first in 1935, the second two years later), and On differential geometry in the large : Minkowski's problem (1938).
• His paper An example of a smooth linear partial differential equation without solution (1957) gave a simple partial differential equation which has no solution, a result which had a substantial impact on the area.

46. Harry Bateman (1882-1946)
• Bateman was awarded a Smith's prize in 1905 for an essay on differential equations.
• Two further papers appeared in print in 1904, namely The solution of partial differential equations by means of definite integrals, and Certain definite integrals and expansions connected with the Legendre and Bessel functions.
• It was during his visit to Gottingen that he learnt of work on integral equations being undertaken by Hilbert and his school.
• One of these 1908 papers is his first publication on transformations of partial differential equations and their general solutions.
• His 1908 paper was on the wave equation.
• He is especially known for his work on special functions and partial differential equations.
• In 1904 he extended Whittaker's solution of the potential and wave equation by definite integrals to more general partial differential equations.
• Bateman was one of the first to apply Laplace transforms to integral equations in 1906.
• In 1910 he solved systems of differential equations discovered by Rutherford which describe radio-active decay.
• The finest contribution Bateman made to mathematics, however, was his work on transformations of partial differential equations, in particular his general solutions containing arbitrary functions.
• In particular he applied his methods to equations resulting from electromagnetics, then later to those arising from hydrodynamics.
• He wrote a number of texts that have been reprinted as classics: The mathematical analysis of electrical and optical wave-motion on the basis of Maxwell's equations (1915, reprinted 1955); Partial differential equations of mathematical physics (1932, reprinted 1944 and 1959); (written with H L Dryden and F D Murnaghan), Hydrodynamics, National Research Council, Washington, D.C.
• (1932, reprinted 1956); and (written with A A Bennett and W E Milne), Numerical integration of differential equations (1933, reprinted 1956).
• He only published five joint papers, one of those in 1924 being with Ehrenfest in which they looked at applications of partial differential equations to electromagnetic fields.

47. Anatoly Mykhailovych Samoilenko (1938-)
• In 1963 he defended his candidate-degree thesis Application of Asymptotic Methods to the Investigation of Nonlinear Differential Equation with Irregular Right-Hand Side.
• In 1974 Samoilenko became a professor and headed the Integral and Differential Equations section within the Department of Mechanics and Mathematics at the Kiev State University.
• In 1987 Samoilenko was appointed head of the Department of Ordinary Differential Equations at the Institute of Mathematics of the Ukrainian Academy of Sciences in Kiev.
• Samoilenko worked on both linear and nonlinear ordinary differential equations.
• In the 1960s he studied nonlinear ordinary differential equations with impulsive action publishing papers such as Systems with pulses at given times (1967).
• His work on boundary-value problems led to papers Numerical-analytic method for the investigation of systems of ordinary differential equations (2 parts both published in 1966) and many other innovative works.
• His most original contribution was the numeric-analytic method for the study of periodic solutions of differential equations with periodic right hand side.
• The latter is known as the method of successive changes of variables and its aim is to ensure the convergence of the iteration process in solving systems of nonlinear differential equations.
• Their work continued over a long period and was written up in the important joint monograph Impulsive Differential Equations (Russian) in 1987.
• In addition to the work mentioned above they worked jointly on the theory of multifrequency oscillation, then later on a system of evolutionary equations with periodic and conditional periodic coefficients.
• This last work was done in collaboration with D Martyniuk and the three of them published, in 1984, the monograph Systems of Evolution Equations with Periodic and Quasiperiodic Coefficients (Russian) giving an excellent account of their results.
• For example, with Mitropolskii and V L Kulik, he wrote Investigation of Dichotomy of Linear Systems of Differential Equations Using Lyapunov Functions (Russian) published in 1990.
• In 1992 they published Numerical-analytic methods in the theory of boundary value problems for ordinary differential equations.
• The book is devoted to the theory of generalized inverses of operators in a Banach space and its applications to linear and weakly nonlinear boundary-value problems for various classes of functional-differential equations, including systems of ordinary differential and difference equations, systems of differential equations with delay, systems with impulse action, and integro-differential systems.
• A recent book by Samoilenko, written with Yu V Teplinskii, is Elements of the mathematical theory of evolution equations in Banach spaces (Ukranian) (2008).
• The book Differential equations : Examples and problems (Russian) (1984) written with S A Krivosheya and N A Perestyuk contains the following authors' summary:- .
• We give the solutions of typical problems in a course on ordinary differential equations.
• The text is structured so as to develop practical skills in students for solving and investigating differential equations describing evolutionary processes in different fields of natural science.
• He is on the Editorial Board of: Nonlinear Oscillations; the Ukrainian Mathematical Journal; Reports of the Ukrainian Academy of Sciences; the Bulletin of the Ukrainian Academy of Sciences; the Ukrainian Mathematical Bulletin; In the World of Mathematics; the Memoirs on Differential Equations and Mathematical Physics; the Miskolc Mathematical Notes; the Georgian Mathematical Journal; and the International Journal of Dynamical Systems and Differential Equations.

48. Thierry Aubin (1942-2009)
• His fundamental papers Metriques riemanniennes et courbure Ⓣ (1970), Equations differentielles non lineaires et probleme de Yamabe concernant la courbure scalaire Ⓣ (1976) and Meilleures constantes dans le theoreme d'inclusion de Sobolev et un theoreme de Fredholm non lineaire pour la transformation conforme de la courbure scalaire Ⓣ (1979) were fundamental in solving the Yamabe problem.
• The analytic problem requires one to prove the existence of a solution of a highly nonlinear (complex Monge-Ampere) differential equation.
• Aubin proved an important special case of the Calabi conjecture in Equations du type Monge-Ampere sur les varietes kahleriennes compactes Ⓣ.
• To understand the scalar curvature equation on the sphere, he introduced the balancing condition on the conformal factors, and provided an improvement in the Sobolev inequality for such factors.
• This became the basic tool of the compactness argument for a lot of subsequent work on this equation and later lead to the solution of prescribing curvature problem with no assumption on the symmetry of the curvature.
• Monge-Ampere equations (1982), writes [',' J L Kazdan, Review: Nonlinear analysis on manifolds.
• Monge-Ampere equations by Thierry Aubin, Bull.
• Monge-Ampere equations by Thierry Aubin, SIAM Review 26 (4) (1984), 593-594.','13]:- .
• This book deals with certain nonlinear partial differential equations which arise from problems in global differential geometry.
• This material is useful in other fields of mathematics such as partial differential equations, to name one.
• Thierry Aubin was a very important mathematician whose work had great influence on the fields of Differential Geometry and Partial Differential Equations.
• Aubin applied these methods in novel ways to fully nonlinear equations, and to delicate semilinear variational problems.
• In the past fifty years there has been a surge of work on problems that involve the interplay of differential geometry and analysis, particularly partial differential equations.

49. Josip Plemelj (1873-1967)
• Plemelj undertook research under von Escherich's supervision and in May 1898 was awarded his doctorate for a thesis on linear homogeneous differential equations with uniform periodical coefficients: uber lineare homogene Differentialgleichungen mit eindeutigen periodischen Koeffizienten Ⓣ.
• An important mathematical event occurred while he was at Gottingen, for that was the year in which Holmgren lectured on Fredholm's theory of integral equations at Gottingen.
• The contributions he made to integral equations and potential theory were brought together in a work he published in 1911 for which he was awarded the Prince Jablonowski Prize.
• Riemann's problem, concerning the existence of a linear differential equation of the Fuchsian class with prescribed regular singular points and monodromy group, had been reduced to the solution of an integral equation by Hilbert in 1905.
• Plemelj discovered equations relating to boundary values of holomorphic functions which are now called the "Plemelj formulae" and shortly after this was able to solve Riemann's problem in his paper Riemannian classes of functions with given monodromy group published in Monatshefte fur Mathematik und Physik Ⓣ in 1908.
• The equations are today important in a number of different fields, including neutron transport theory where a singular integral equation is encountered.
• Plemelj's methods for solving the Riemann's problem were further developed by Nikolai Ivanovich Mushelisvili into the theory of singular integral equations.
• Within the theory of differential equations he worked mostly on equations of the Fuchs type and on Klein's theorems.
• He used to hold a general course of mathematics and a three-year cycle of lectures on differential equations, the theory of analytic functions, and algebra including number theory.
• They were The theory of analytic functions (1953), Differential and integral equations.

50. Roy Kerr (1934-)
• He submitted his doctoral thesis Equations of Motion in General Relativity in 1958 and published the results of the thesis in three papers entitled The Lorentz-covariant approximation method in general relativity in Nuovo Cimento in 1959.
• It is found that as well as the usual equations of motion and energy derived by Einstein, Infeld and Hoffman for the quasi-static approximation, there are three further equations, the equations of spin, which must be satisfied by the structural parameters of each particle.
• These equations also appear as surface integral conditions in the quasi-static approximation.
• It is only the differential equations satisfied by these that change in the higher orders.
• In this first paper the equations of motion of a pole-dipole particle are calculated to the first approximation, and in the second paper this is continued to the second approximation.
• In the third paper the method is applied to the combined Einstein-Maxwell equations.
• In 1963, Roy Kerr, a New Zealander, found a set of solutions of the equations of general relativity that described rotating black holes.
• In my entire scientific life, extending over forty-five years, the most shattering experience has been the realization that an exact solution of Einstein's equations of general relativity, discovered by the New Zealand mathematician, Roy Kerr, provides the absolutely exact representation of untold numbers of massive black holes that populate the universe.
• Everybody who tried to solve the problem was going at it from the front, but I was trying to solve the equation from a different point of view - there were a number of new mathematical methods coming into relativity at the time and Josh [Goldberg] and I had had some success with these.
• I was trying to look at the whole structure - the Bianchi identities, the Einstein equations and these Tetrads - to see how they fitted together and it all seemed to be pretty nice and it looked like lots of solutions were going to come out.
• He, Papapetrou, had been trying for 30 years to find such a solution to Einstein's equation and had failed, as had other relativists.
• In 1965, in collaboration with Alfred Schild who was a colleague at the University of Texas, Kerr published Some algebraically degenerate solutions of Einstein's gravitational field equations which introduced what are today known as Kerr-Schild spacetimes and the Kerr-Schild metric.
• In the early 1960s Professor Kerr discovered a specific solution to Einstein's field equations which describes a structure now termed a Kerr black hole.

51. Volodymyr Petryshyn (1929-)
• from Columbia University for his thesis Linear Transformations Between Hilbert Spaces and the Application of the Theory to Linear Partial Differential Equations.
• In 1962, Direct and iterative methods for the solution of linear operator equations in Hilbert space was published which does much toward developing a unified point of view toward a number of important methods of solving linear equations.
• In the same year, The generalized overrelaxation method for the approximate solution of operator equations in Hilbert space appeared and in the following year the two papers On a general iterative method for the approximate solution of linear operator equations and On the generalized overrelaxation method for operation equations.
• His major results include the development of the theory of iterative and projective methods for the constructive solution of linear and nonlinear abstract and differential equations.
• He has shown that the theory of A-proper type maps not only extends and unifies the classical theory of compact maps with some recent theories of condensing and monotone-accretive maps, but also provides a new approach to the constructive solution of nonlinear abstract and differential equations.
• The theory has been applied to ordinary and partial differential equations.
• Approximation-solvability of Nonlinear Functional and Differential Equations appeared in December 1992:- .
• This outstanding reference/text develops an essentially constructive theory of solvability on linear and nonlinear abstract and differential equations involving A-proper operator equations in separable Banach spaces, treats the problem of existence of a solution for equations involving pseudo-A-proper and weakly-A-proper mappings, and illustrates their applications.
• Facilitating the understanding of the solvability of equations in infinite dimensional Banach space through finite dimensional approximations, Approximation - solvability of Nonlinear Functional and Differential Equations: offers an important elementary introduction to the general theory of A-proper and pseudo-A-proper maps; develops the linear theory of A-proper maps; furnishes the best possible results for linear equations; establishes the existence of fixed points and eigenvalues for P-gamma-compact maps, including classical results; provides surjectivity theorems for pseudo-A-proper and weakly-A-proper mappings that unify and extend earlier results on monotone and accretive mappings; shows how Friedrichs' linear extension theory can be generalized to the extensions of densely defined nonlinear operators in a Hilbert space; presents the generalized topological degree theory for A-proper mappings; and applies abstract results to boundary value problems and to bifurcation and asymptotic bifurcation problems.
• In 1995 his second monograph Generalized Topological Degree and Semilinear Equations appeared in print, published by Cambridge University Press.
• In this monograph we develop the generalised degree theory for densely defined A-proper mappings, and then use it to study the solubility (sometimes constructive) and the structure of the solution set of [an] important class of semilinear abstract and differential equations ..
• A-proper mappings arise naturally in the solution to an equation in infinite dimensional space via the finite dimensional approximation..
• Using these tools, the author defines the generalised topological degree for densely defined A-proper mappings, gives applications to the solubility of an important class of semilinear abstract and differential equations, and discusses global bifurcation results.

52. Jen Egerváry (1891-1958)
• Following a suggestion by Fejer, Egervary studied a class of integral equations of second kind in which the kernel is a periodic function and the matrix of the approximating system of algebraic equations is cyclic.
• He submitted his thesis On a class of integral equations (Hungarian), was examined on mathematics, theoretical physics and cosmography and, after the publication of his thesis in the Hungarian Mathematical and Physical Journal, he was awarded a Ph.D.
• The 1922 papers are On a maximum-minimum problem and its connexion with the roots of equations, and A minimization problem for a symmetric multilinear form (Hungarian).
• In 1930 he published the paper On the trinomial equation (Hungarian).
• This paper is discussed at length by Peter Gabor Szabo in [',' P G Szabo, On the roots of the trinomial equation, CEJOR Cent.
• In 1930, Egervary published a paper on the arrangements of the roots of trinomial equations in the complex plane.
• The central idea here came from an interesting observation: the roots of the trinomial equations can be interpreted as the equilibrium points of unit masses that are located at the vertices of two regular concentric polygons centred at the origin in the complex plane.
• In this separation Egervary determined sectors in the complex plane, where each sector contains a root of the equation, and the sum of the angles of these sectors is of order π/2.
• However, at this time, he also became interested in algebraic equations.
• For about 15 years, starting in 1938, he published his results in geometry and differential equations.
• In addition to his work at the Technical University, almost every year he taught courses on differential equations at Eotvos Lorand University in Budapest.

53. Vito Volterra (1860-1940)
• In 1890 Volterra showed by means of his functional calculus that the theory of Hamilton and Jacobi for the integration of the differential equations of dynamics could be extended to other problems of mathematical physics.
• During the years 1892 to 1894 Volterra published papers on partial differential equations, particularly the equation of cylindrical waves.
• His most famous work was done on integral equations.
• He began this study in 1884 and in 1896 he published papers on what is now called 'an integral equation of Volterra type'.
• He continued to study functional analysi applications to integral equations producing a large number of papers on composition and permutable functions.
• It was this principle which he applied to his celebrated researches on integral equations of Volterra's type.
• He considered heuristically the integral equations as a limiting case of a system of linear algebraic equations and then checked his final formulae directly.
• He studied the Verhulst equation and the logistic curve.
• He also wrote on predator-prey equations.
• In December 1938 he was affected by phlebitis: the use of his limbs was never recovered, but his intellectual energy was unaffected, and it was after this that his two last papers 'The general equations of biological strife in the case of historical actions' and 'Energia nei fenomeni elastici ereditarii' were published by the Edinburgh Mathematical Society and the Pontifical Academy of Sciences respectively.

54. James Ezeilo (1930-2013)
• It was Cartwright who became Ezeilo's thesis supervisor and advised him during his research on ordinary differential equations.
• He was awarded a doctorate in 1959 for his thesis Some Topics in the Theory of Ordinary Non-linear differential Equations of the Third Order although he had submitted his thesis and had been examined in 1958.
• The first few papers are On the boundedness of solutions of a certain differential equation of the third order (1959), On the stability of solutions of certain differential equations of the third order (1960), On the existence of periodic solutions of a certain third-order differential equation (1960), and A note on a boundedness theorem for some third order differential equations (1961).
• The results of the 1959 paper are of the same type as the ones obtained for second order equations by Mary Cartwright in her 1950 paper Contributions to the theory of nonlinear oscillations.
• James Ezeilo's early research dealt mainly with the problem of stability, boundedness, and convergence of solutions of third order ordinary differential equations.
• Apart from extending known results and techniques to higher order equations, the main thrust of his work was the construction of Lyapunov-like functions, which he did elegantly and used to study the qualative properties of solutions.
• In addition he was a pioneer in the use of Leray-Schauder degree type arguments to obtain existence results for periodic solutions of ordinary differential equations.
• Among his last papers to be published we mention Some third order differential equations in physics which he co-authored with Alexander Animalu, Non resonant oscillations for some fourth order differential equations (Part I in 1999, Part II in 2001, Part III in 1999), Periodic boundary value problems for some fourth order differential equations (2000), and Further instability theorems for some fourth order differential equations (2000).

55. Aleksei Alekseevich Dezin (1923-2008)
• The authors of [',' V S Vladimirov, V A Il’in, I S Lomov, E I Moiseev, B V Pal’tsev, V K Romanko, V A Sadovnichii and I A Shishmarev Aleksei Alekseevich Dezin, Differential Equations 44 (12) (2008), 1773-1775.','12] write about Aleksei Alekseevich junior's extremely difficult upbringing:- .
• He continued to undertake research at Moscow State University advised by Sergei Lvovich Sobolev and was awarded his candidate's degree (equivalent to a Ph.D.) in 1956 for his thesis Boundary Value Problems for Symmetric Systems of Partial Differential Equations.
• He had begun writing research papers while still an undergraduate [',' V S Vladimirov, V A Il’in, I S Lomov, E I Moiseev, B V Pal’tsev, V K Romanko, V A Sadovnichii and I A Shishmarev Aleksei Alekseevich Dezin, Differential Equations 44 (12) (2008), 1773-1775.','12]:- .
• Before the award of his doctorate he had published several papers in Russian: On imbedding theorems and the problem of continuation of functions (1953); The second boundary problem for the polyharmonic equation in the space W2m (1954); Mixed problems for certain symmetric hyperbolic systems (1956); Concerning solvable extensions of the first order partial linear differential operators (1956); and Mixed problems for certain parabolic systems (1956).
• papers concerned extension of functions, embedding theorems, and also an analysis of conditions for solubility of the second boundary-value problem for polyharmonic equations.
• This was written in a period when he was publishing a particularly outstanding series of papers on invariant systems of first-order partial differential equations on smooth Riemannian manifolds.
• These had the ultimate aim of trying to understand the structure of the Cauchy-Riemann equations in the plane.
• These papers include Existence and uniqueness theorems for solutions of boundary problems for partial differential equations in function spaces (1959), Boundary value problems for invariant elliptic systems (1960), and Invariant elliptic systems of equations (1960).
• An English translation with title Partial differential equations.
• Howard Levine writes [',' H A Levine, Review: Partial Differential Equations: An Introduction to a General Theory of Linear Boundary Value Problems by Aleksei A Dezin, SIAM Review 30 (4) (1988), 672-673.','5]:- .
• The author has intended this book to be an introduction to a general theory of boundary value problems for linear partial differential equations accessible to graduate students as well as researchers.
• In simplest terms, this is a book about separation of variables in partial differential equations.
• More accurately, the book may be considered an introduction to the use of spectral theory in solving initial- and two- point boundary value problems for ordinary differential equations with unbounded operator coefficients.
• Dezin's next little book of 63 pages Equations, operators, spectra (1984) shows him to be a skilful and an innovative expositor.
• Assume that you meet someone who knows only the elements of mathematics, for instance how to solve a system of two linear equations with two unknowns, but is eager to learn more, and you want to inform this person about the meaning of spectral theory of linear operators.
• The potential reader is transported from very simple systems of linear equations to concepts as complex as that of linear space, invertible operator, eigenvalue and eigenvector, norm, adjoint, unitary and selfadjoint operator.
• We describe special difference models of equations of mathematical physics, models of boundary value problems and objects of quantum mechanics.
• He was married to Nataliya Borisovna and their home [',' V S Vladimirov, V A Il’in, I S Lomov, E I Moiseev, B V Pal’tsev, V K Romanko, V A Sadovnichii and I A Shishmarev Aleksei Alekseevich Dezin, Differential Equations 44 (12) (2008), 1773-1775.','12]:- .

• The numerical methods for solving the kinetic equation of neutron transfer in nuclear reactors which he presented in 1952 is now known as the 'Vladimirov method'.
• In this thesis he presented his theoretical investigation of the numerical solution, using the method of characteristics, of the single-velocity transport equation for a multilayered sphere.
• There he worked under Mikhail Alekseevich Lavrent'ev and he published the important paper On the application of the Monte Carlo methods for obtaining the lowest characteristic number and the corresponding eigenfunction for a linear integral equation in 1956.
• Thus, he first proved the theorem on the uniqueness, existence, and smoothness of the solution of the single-velocity transport equation, established properties of the eigenvalues and eigenfunctions, and gave a new variational principle (the Vladimirov principle).
• His thesis contained what is today known as the 'Vladimirov variational principle' which he applied to the one-velocity transport equation and derived the best boundary conditions in the method of spherical harmonics for convex regions.
• In 1967 Vladimirov published the book The equations of mathematical physics (Russian) which was written at advanced undergraduate or beginning graduate level.
• Vidar Thomee writes in a review [',' V Thomee, Review: Equations of Mathematical Physics, by V S Vladimirov, Mathematics of Computation 26 (118) (1972), 593-594.','20] that the book:- .
• contains a comprehensive treatment of the standard boundary value problems for second order partial differential equations.
• Ruben Hersh writes [',' R Hersh, Review: Equations of Mathematical Physics, by V S Vladimirov, American Scientist 61 (1) (1973), 86.','14]:- .
• It is clear and well organised and contains much important material that is not presented in other introductory texts on partial differential equations.

• Much of Faddeev's early work had been done in collaboration with Delone, particularly the highly significant results he obtained on Diophantine equations.
• 3, 223-231.','2] his early results on Diophantine equations are described:- .
• Faddeev's very first results in Diophantine equations were remarkable.
• He was able to extend significantly the class of equations of the third and fourth degree that admit a complete solution.
• When he was studying, for example, the equation x3 + y3 = A, Faddeev found estimates of the rank of the group of solutions that enabled him to solve the equation completely for all A ≤ 50.
• For the equation x4 + Ay4 = ±1 he proved that there is at most one non-trivial solution; this corresponds to the basic unit of a certain purely imaginary field of algebraic numbers of the fourth degree and exists only when the basic unit is trinomial.
• This work included the results on Diophantine equations described in the above quotation and a wealth of other material.
• Much of this work was done in collaboration with his wife Vera Nikolaevna Faddeeva but his first few papers on this topic are single authored: On certain sequences of polynomials which are useful for the construction of iteration methods for solving of systems of linear algebraic equations (1958), On over-relaxation in the solution of a system of linear equations (1958), and On the conditionality of matrices (1959).
• The problems are grouped under seven heads: Complex Numbers, Determinants, Linear Equations, Matrices, Polynomials and Rational Functions of a single Indeterminate, Symmetric Functions, and Linear Algebra.

58. Leonid Vital'evich Kantorovich (1912-1986)
• Kantorovich gave two lectures, "On conformal mappings of domains" and "On some methods of approximate solution of partial differential equations".
• In 1936 he published On one class of functional equations (Russian) in which he applied semiordered spaces to numerical methods.
• The method of successive approximations is often applied to proving existence of solutions to various classes of functional equations; moreover, the proof of convergence of these approximations leans on the fact that the equation under study may be majorised by another equation of a simple kind.
• Similar proofs may be encountered in the theory of infinitely many simultaneous linear equations and in the theory of integral and differential equations.
• Consideration of semiordered spaces and operations between them enables us to easily develop a complete theory of such functional equations in abstract form.
• The authors are particularly concerned with applications of functional analysis to the theory of approximation and the theory of existence and uniqueness of solutions of differential and integral equations (both linear and non-linear).
• These other areas include functional analysis and numerical analysis and within these topics he published papers on the theory of functions, the theory of complex variables, approximation theory in which he was particularly interested in using Bernstein polynomials, the calculus of variations, methods of finding approximate solutions to partial differential equations, and descriptive set theory.
• The most interesting thing here was the paralleling of calculations for integrating the differential equation for the Bessel functions on these machines.

• In dealing with simultaneous equations, Zhu certainly presented improvements, giving a method essentially equivalent to Gauss's pivotal condensation.
• He treats polynomial algebra, and polynomial equations, by the "coefficient array method" or "method of the celestial unknown" which had been developed in northern China by the earlier thirteenth century Chinese mathematicians, but up till that time had not spread to southern China.
• Zhu, however, wants to illustrate something more advanced than solving a quadratic equation.
• Although we cannot be certain that Zhu's methods are exactly what we have presented here, he certainly arrived at the equation (2).
• He has illustrated how to work with the four unknowns x, y, z, t and he can now illustrate how to solve a quartic equation.
• It is phrased in terms of a right angled triangle, but the conditions are so artificial that he is really simply giving a system of equations.
• The following problem in the Siyuan yujian is reduced by Zhu to a polynomial equation of degree 5 (see [',' J Hoe, Zhu Shijie and his Jade mirror of the four unknowns, in First Australian Conference on the History of Mathematics (Clayton, 1980) (Clayton, 1981), 103-134.','7] for a detailed solution as given by Zhu):- .
• The Siyuan yujian also contains a transformation method for the numerical solution of equations which is applied to equations up to degree 14.
• This is based on the method to solve polynomial equations which was rediscovered by Horner and Ruffini.

60. J E Littlewood (1885-1977)
• In the late 1930's the Department of Scientific and Industrial Research tried to interest pure mathematicians in nonlinear differential equations which were important for radio engineers and scientists because they described the behaviour of electric circuits.
• The impending war motivated this interest and in 1938 the Radio Research Board asked British pure mathematicians for help in dealing with certain types of nonlinear differential equations arising in radio engineering.
• Littlewood, working jointly with Mary Cartwright, spent 20 years working on equations of this type such as van der Pol's equation.
• Monthly 103 (10) (1996), 833-845.','16], and in particular the work on van der Pol's equation is discussed in [',' S L McMurran and J J Tattersall, Cartwright and Littlewood on van der Pol’s equation, in Harmonic analysis and nonlinear differential equations, Riverside, CA, 1995, Contemp.
• Van der Pol's experiments with nonlinear oscillators during the 1920s and 1930s stimulated mathematical interest in nonlinear differential equations arising in radio research.
• Cartwright and Littlewood's analysis of the van der Pol equation and its generalizations led them to explore some interesting topological methods, including the development of a fixed-point theorem for continua invariant under a homeomorphism of the plane.
• in recognition of his distinguished contributions to many branches of analysis, including Tauberian theory, the Riemann zeta-function, and non-linear differential equations.

61. Ehrenfried Walter von Tschirnhaus (1651-1708)
• He showed Collins and Wallis his methods for solving equations, but these turned out to be special cases of known results.
• In it he discussed several mathematical questions including the solution of higher equations.
• In his letter Leibniz also criticises Tschirnhaus's solution of algebraic equations.
• Tschirnhaus worked on the solution of equations and the study of curves.
• He discovered a transformation which, when applied to an equation of degree n, gave an equation of degree n with no term in xn-1 and xn-2.
• We have indicated above that he had already discussed his methods for solving equations with Leibniz who had pointed out difficulties.
• Nevertheless Tschirnhaus published his transformation in Acta Eruditorum in 1683 and, in this article, showed how it could be used to solve the general cubic equation.
• However, his belief that the method would allow an equation of any degree to be solved is false as had already been pointed out to him by Leibniz.
• History Topics: Quadratic, cubic and quartic equations .

62. Louis Mordell (1888-1972)
• Rather remarkably, Mordell's future research interests were determined by these books, and his love of indeterminate equations came from this period.
• For his Smith's Prize essay Mordell studied solutions of y2 = x3 + k, an equation which had been considered by Fermat.
• Thue had already proved a result which, combined with Mordell's work showed that this equation had only finitely many solutions but Mordell only learned about Thue's work at a later date.
• However he solved the equation for many values of k, giving complete solutions for some values.
• Mordell was awarded the second Smith's Prize with his essay, and he went on to publish a long paper on this equation, now sometimes called Mordell's equation, in the Proceedings of the London Mathematical Society.
• Mordell submitted his subsequent work on indeterminate equations of the third and fourth degree when he became a candidate for a Fellowship at St John's College, but he was not successful.
• Indeterminate equations have never been very popular in England (except perhaps in the 17th and 18th centuries); though they have been the subject of many papers by most of the greatest mathematicians in the world: and hosts of lesser ones ..
• marks the greatest advance in the theory of indeterminate equations of the 3rd and 4th degrees since the time of Fermat; and it is all the more remarkable that it can be proved by quite elementary methods.
• He emphasised the fact that he was returning to Cambridge where he began his career by taking the equation y2 = x3 + k as the topic for his inaugural lecture to the Sadleirian Chair.

63. Oskar Klein (1894-1977)
• He defended his doctorate in 1921 at Stockholm Hogskola and was opposed by Erik Ivar Fredholm the mathematical physicist best known for his work on integral equations and spectral theory.
• In a paper in which he determined the atomic transition probabilities (prior to Dirac), he introduced the initial form of what would become known as the Klein-Gordon equation.
• The Klein-Gordon equation was the first relativistic wave equation.
• The equation can be written: .
• It is interesting to note that this equation appeared exactly as it has been written in David Bohm's 1951 book Quantum Theory but was not called the Klein-Gordon equation.
• However, Bethe and Jackiw's Intermediate Quantum Mechanics, originally written in 1964, does refer to the same equation as the Klein-Gordon equation.
• Klein and Walter Gordon were thus eventually honoured with having the equation named after them, though it seems to have taken over a quarter of a century to receive the honour.
• Oddly enough, Schrodinger himself privately developed a relativistic wave equation from his original wave equation, which, in reality, was not that difficult to do, and did so prior to Klein and Gordon, though he never published his results.
• The trouble came when the equation did not result in the correct fine structure of the hydrogen atom and when Pauli introduced the concept of spin a year later (1927).
• The equation turned out to be incompatible with spin and, as a result, is only useful for calculations involving spinless particles.
• He and Jordan showed that one can quantize the non-relativistic Schrodinger equation and, in honour of this work, he was the recipient of yet another named mathematical tool, the Jordan-Klein matrices.
• Despite the so-called Klein paradox, that being that the positron was not completely understood by physicists, he was able to convince physicists of the soundness of Dirac's relativistic wave equation.
• Of the many he helped, one included Walter Gordon who would later join Klein in being the beneficiaries of the named equation we have just discussed.

64. Fischer Black (1938-1995)
• The Black-Scholes-Merton partial differential equation for the price of a financial asset was derived in their famous paper [','Black F.
• (1973), The Pricing of Options and Corporate Liabilities, Journal of Political Economy, 81(3), 637-54.','15] which derived and solved the Black-Scholes-Merton differential equation thereby solving the stock-option pricing problem [Note 1: THIS LINK] .
• the model of the stock-price in continuous time was represented by a special type of differential equation (so called stochastic differential equation) which allowed for randomness in stock-price.
• The differential equation for the stock-price, S(t), was:- .
• When the above differential equation was integrated, it gave a stock-price distribution that was lognormal (i.e.
• (1951), On stochastic differential equations, Memoirs, American Mathematical Society, 4, 1-51.','95], to derive how the price, f (S, t), of the stock-option would change if the stock-price, S(t), changed (a kind of beta for the option-price versus the stock-price i.e.
• (1973), The Pricing of Options and Corporate Liabilities, Journal of Political Economy, 81(3), 637-54.','15] has two ways of deriving the relevant partial differential equation.
• Putting a = μS(t) and b = σS(t) in Ito's Lemma and exploiting that there are no free lunches in a randomless/riskless portfolio, gave rise to the famous partial differential equation:- .
• This equation is satisfied by the traded assets themselves, for example, f (S, t) = S(t) and by f (S, t) = A ert but these do not have the European call-option boundary conditions (at time T) that Black and Scholes were interested in (i.e.
• By 1969, Black and Scholes had the above differential equation.
• They tried to solve this partial differential equation with the European call-option boundary condition but could not solve it.
• But Black and Scholes had noticed the curious absence (in the differential equation) of the investment return, μ, of the stock-price or any parameter representing the degree of preference, as to risk, on the part of option purchasers.
• the return was the risk-free rate, irrespective of the purchaser's risk preferences, they found that Sprenkle's formula, with these adjustments, satisfied the partial differential equation.
• It is clear that the unexpected aspect of the Black-Scholes-Merton differential equation was not at first accepted.
• (1967), The Random Character of Stock Market Prices, MIT Press, Cambridge, Massachusetts (contains the translation from French of Bachelier’s doctoral thesis and contains Sprenkle’s, 1961 paper).','88] the close connection between random walks and the Fourier heat equation, something that was expanded on by Kac, in 1951, [','Ito K.
• (1948), Space-time approach to non-relativistic quantum mechanics, Review of Modern Physics, 20, 367-387.','89], where it was shown that the solution of Fourier's equation could be expressed as the distribution function of a random variable arising of a large number of random walks each with n steps (and with each step size proportional to √(t/n)) and by letting n become very large (i.e.

65. Evelyn Nelson (1943-1987)
• The first of her two children, both daughters, was born shortly before she competed the work for her doctoral thesis The lattice of equational classes of commutative semigroups.
• In addition to The lattice of equational classes of commutative semigroups referred to above, she published in 1971 the papers Embedding the dual of πm in the lattice of equational classes of commutative semigroups in the Proceedings of the American Mathematical Society and Embedding the dual of π∞ in the lattice of equational classes of semigroups in Algebra Universalis, both written jointly with Stanley Burris.
• In the same year she published The lattice of equational classes of semigroups with zero in the Canadian Mathematical Bulletin.
• Two which Nelson wrote jointly with Bernhard Banaschewski were On residual finiteness and finite embeddability and Equational compactness in equational classes of algebras both of which were published in Algebra Universalis.
• In the following year she published Equational compactness in infinitary algebras again jointly with Bernhard Banaschewski.
• W Taylor recently proved, among other results, that an equational class of finitary algebras contains enough equationally compact algebras if and only if the subdirectly irreducible algebras in the class constitute, up to isomorphism, a set.
• This note provides a negative answer to the natural question whether the same equivalence holds for equational classes of infinitary algebras by exhibiting examples in which there are, up to isomorphism, only one subdirectly irreducible algebra in the class and no non-trivial equationally compact algebras at all.

66. Jacques-Louis Lions (1928-2001)
• Schwartz had made a big breakthrough in the understanding of partial differential equations which he saw should be completely recast in the context of distribution theory.
• Lions was one of several students who Schwartz directed to take this new approach and his doctoral thesis developed what has become the standard variational theory of linear elliptic and evolution equations.
• In one of these collaborations with Enrico Magenes, they were investigating inhomogeneous boundary problems for elliptic equations and inhomogeneous initial-boundary value problems for parabolic and hyperbolic evolution equations.
• It is a work to be recommended to every serious student of partial differential equations and particularly to those who are fascinated by the manner in which modern functional analysis has aided and influenced their study.
• The systems he had in mind are those described by linear and nonlinear partial differential equations.
• He had already published a major work on control of systems Controle optimal de systemes gouvernes par des equations aux derivees partielles Ⓣ in 1968 which investigates deterministic optimisation problems involving partial differential equations.
• One notable feature of this work is that Lions introduces an infinite dimensional version of the Riccati equation in it.
• reports on methods of solving nonlinear boundary value problems for partial differential equations, on a theoretical and functional analysis basis.
• Integral equations and numerical methods.
• The first volume covered his work on Partial differential equations and Interpolation, the second volume contained Control and Homogenization, and the third volume Numerical analysis, Scientific computation and Applications.
• The models used in that field consist of complex sets of partial differential equations, including the Navier-Stokes equations and the equations of thermodynamics.
• In spite of what Lions himself liked to call the 'truly diabolical' complexity of the set of partial differential equations, boundary conditions, transmission conditions, nonlinearities, physical hypotheses, etc., that appeared in those models, Lions, in collaboration with Roger Temam and Shou Hong Wang, was able to study the questions of the existence and uniqueness of solutions, to establish the existence of attractors, and to do a numerical analysis of these models.
• Finally, with Vivette Girault, he worked until January 2001 on perfecting a finite element method using two meshes, one 'rough' and one 'fine', for the numerical simulation of the Navier-Stokes equations.

67. Harry Schmidt (1894-1951)
• Another major publication during these years was his introduction to the theory of the wave equation Einfuhrung in die Theorie der Wellengleichung Ⓣ (1931).
• While he was working at the laboratory Schmidt published, jointly with Kurt Schroder, a comprehensive report on the theory of laminar boundary layers deals with the basic conceptions and equations Laminare Grenzschichten.
• The general equations of motion of hydrodynamics: .
• The equation of continuity, the impulse theorem and the Navier-Stokes equations.
• The equations of motion in orthogonal curvilinear coordinates.
• Introduction of the boundary layer equation: .
• A rigorous solution of the Navier-Stokes equations as an example.
• The fundamental equations.
• The equations of a steady two-dimensional motion with respect to the stream lines and their orthogonal trajectories.

68. Henry Heaton (1846-1927)
• Required the equation of the curve the duck described, and the distance it swam to reach the shore.
• While there he published the paper [',' H Heaton, Cubic equations, The Analyst 5 (4) (1878), 117-118.','3] on cubic equations.
• In this paper Heaton solved the cubic equation x3 - 3ax = 2b by putting x = 2√a cos t.
• Then the original equation becomes 2cos 3t = 2b/(a√a) so .
• In 1896 Heaton, who was now County Surveyor, published [',' H Heaton, A method of solving quadratic equations, The American mathematical Monthly 3 (10) (1896), 236-237.','2], namely A Method of Solving Quadratic Equations in the American Mathematical Monthly.
• Let it be required to solve the equation .

69. Wilhelm Ljunggren (1905-1973)
• Papers such as Fermat's problem by Øystein Ore and On the indeterminate equation x2 - Dy2 = 1 by Trygve Nagell were in the issue which contained the problems that he solved to win his prize and, through studying these and other papers, he was already interested in number theory before beginning his university course.
• Almost all of Ljunggren's research was on Diophantine equations.
• For example in A note on simultaneous Pell equations (1941) Ljunggren studied the simultaneous Pell equations .
• One of Ljunggren's main interests was Diophantine equations of degree 4.
• In 1923 Mordell showed that the Diophantine equation .
• In the paper Ljunggren found bounds for the number of integer solutions for some special equations of this type.
• In the first of these he proves that the equation in question has at most two positive integer solutions and gives an example of D = 1785 which does indeed have two solutions, namely x = 13, y = 4 and x = 239, y = 1352.
• He proved that the equation .

70. Józeph Petzval (1807-1891)
• He was influenced by the work of Liouville and wrote both a long paper and a two volume treatise on the Laplace transform and its application to ordinary linear differential equations.
• in the [19th] century [Hungarian] scientists obtained particularly nice results in the theory of differential equations.
• special mention must be made of Jozef Petzval who, after a whole range of articles on remarkable results of his own, around the middle of the [19th] century published a two-volume monograph on differential equations that was the only guide in the field for a long time [Integration der linearen Differentialgleichungen Ⓣ (Vol.
• Among his original results, the most important ones concern the singular solutions to linear differential equations with a complex variable.
• The nowadays fairly complete theory of Riccati's differential equations owes a lot to him.
• Secondly, he was a firm believer in scientific discoveries being firmly mathematically based and only if one could describe the science via differential equations was it, for him, proper science.
• His attack was based on the fact that Doppler derived the principle in a few lines using only simple equations.
• Without the application of differential equations, it is not possible to enter the realms of great science.
• His opponent [Petzval] bandied with such expressions as 'great science' and 'small science' in the Austrian Academy of Sciences, being of the opinion that great truths could not be found in a few lines and through an equation with only one unknown, and that at least one differential equation is necessary - and in this way he believes to have shown the incorrectness of the Doppler principle.
• He lectured on optics, linear and differential equations, analytical mechanics, acoustics, ballistics and mechanical vibrations.

71. Edward Waring (1736-1798)
• We shall comment further below on this important work, covering topics in the theory of equations, number theory and geometry.
• Meditationes Algebraicae, covering the theory of equations and number theory, appeared in 1770 with an expanded version in 1782.
• In Meditationes Algebraicae Waring proves that all rational symmetric functions of the roots of an equation can be expressed as rational functions of the coefficients.
• He derived a method for expressing symmetric polynomials and he investigated the cyclotomic equation xn - 1 = 0.
• The most significant aspect of Waring's treatment of this example is the symmetric relation between the roots of the quartic equation and its resolvent cubic.
• k equations in k unknowns can be reduced to one equation with one unknown.
• His result that the product of the degrees of the original equations is the degree of the single reduced equation is known as the Generalised Theorem of Bezout.

72. Rudolf Kalman (1930-)
• Thus, such a system can be described by a finite number of simultaneous ordinary differential equations.
• A nonlinear differential equation of the Riccati type is derived for the covariance matrix of the optimal filtering error.
• The solution of this 'variance equation' completely specifies the optimal filter for either finite or infinite smoothing intervals and stationary or non-stationary statistics.
• The variance equation is closely related to the Hamiltonian (canonical) differential equations of the calculus of variations.
• The significance of the variance equation is illustrated by examples which duplicate, simplify, or extend earlier results in this field.
• Properties of the variance equation are of great interest in the theory of adaptive systems.
• Not only have they led to eminently useful developments, such as the Kalman-Bucy filter, but they have contributed to the rapid progress of systems theory, which today draws upon mathematics ranging from differential equations to algebraic geometry.
• Among his many outstanding contributions were the formulation and study of most fundamental state-space notions (including controllability, observability, minimality, realizability from input/output data, matrix Riccati equations, linear-quadratic control, and the separation principle) that are today ubiquitous in control.

73. Robert Murphy (1806-1843)
• Murphy then goes on to correctly point out the errors in the Reverend John Mackey's arguments using only Euclid's Elements and Cardan's Ars Magna (more precisely the Cardan-Tartaglia formula for solving cubic equations).
• Murphy published On the General Properties of Definite Integrals (1830), On the Resolution of Algebraical Equations (1831), First Memoir on the Inverse Method of Definite Integrals, with Physical Applications (1830) and On Elimination between an Indefinite Number of Unknown Quantities (1832) in the Transactions of the Cambridge Philosophical Society.
• We can already see the two main areas on which Murphy was working, namely on integral equations and algebraic equations.
• On the theory of equations Murphy wrote papers such as On the Existence of Real or Imaginary Root to Any Equation (1833), Further Development of the Existence of a Real or Imaginary Root to Any Equation (1833), Analysis of the Roots of Equations (1837) and the results from these papers were all contained in Murphy's 1839 book A Treatise on the Theory of Algebraical Equations.
• The book also included a description of the work on others on the theory of equations.
• His book A Treatise on the Theory of Algebraical Equations was published in 1839 and provided much need funds.

74. François Viète (1540-1603)
• In 1593 Roomen had proposed a problem which involved solving an equation of degree 45.
• (If I asked for a solution to ax = b nobody asks: "For which quantity do I solve the equation ?") .
• Viete made many improvements in the theory of equations.
• However, if we are to be strictly accurate we should say that he did not solve equations as such but rather he solved problems of proportionals which he states quite explicitly is the same thing as solving equations.
• Viete therefore looked for solutions of equations such as A3 + B2A = B2Z where, using his convention, A was unknown and B and Z were knowns.
• He presented methods for solving equations of second, third and fourth degree.
• He knew the connection between the positive roots of equations and the coefficients of the different powers of the unknown quantity.
• When Viete applied numerical methods to solve equations as he did in De numerosa potestatum he gave methods which were similar to those given by earlier Arabic mathematicians.
• For example his methods are compared with those of Sharaf al-Din al-Tusi in the paper [',' J Borowczyk, Preuve et complexite des algorithmes de resolution numerique d’equations polynomiales d’al-Tusi et de Viete, in Deuxieme Colloque Maghrebin sur l’Histoire des Mathematiques Arabes (Tunis, 1988), 27-52.','11] and [',' R Rashed, Resolution des equations numeriques et algebre : Saraf-al-Din al-Tusi , Viete (French), Arch.
• In [',' R Rashed, Resolution des equations numeriques et algebre : Saraf-al-Din al-Tusi , Viete (French), Arch.
• Although this seems to make Harriot's dependence on Viete clear, one would have to say that the two men give very similar approaches to solving equations algebraically, yet Harriot shows deeper understanding than does Viete.
• History Topics: Quadratic, cubic and quartic equations .

75. Oliver Heaviside (1850-1925)
• Despite this hatred of rigour, Heaviside was able to greatly simplify Maxwell's 20 equations in 20 variables, replacing them by four equations in two variables.
• Today we call these 'Maxwell's equations' forgetting that they are in fact 'Heaviside's equations'.
• He introduced his operational calculus to enable him to solve the ordinary differential equations which came out of the theory of electrical circuits.
• He replaced the differential operator d/dx by a variable p transforming a differential equation into an algebraic equation.
• The solution of the algebraic equation could be transformed back using conversion tables to give the solution of the original differential equation.

76. Benjamin Moiseiwitsch (1927-2016)
• This graduate-level text's primary objective is to demonstrate the expression of the equations of the various branches of mathematical physics in the succinct and elegant form of variational principles (and thereby illuminate their interrelationship).
• Chapter-by-chapter treatment consists of analytical dynamics; optics, wave mechanics, and quantum mechanics; field equations; eigenvalue problems; and scattering theory.
• In 1977 he published Integral Equations.
• Two distinct but related approaches hold the solutions to many mathematical problems - the forms of expression known as differential and integral equations.
• The method employed by the integral equation approach specifically includes the boundary conditions, which confers a valuable advantage.
• In addition, the integral equation approach leads naturally to the solution of the problem - under suitable conditions - in the form of an infinite series.
• Geared toward upper-level undergraduate students, this text focuses chiefly upon linear integral equations.
• It begins with a straightforward account, accompanied by simple examples of a variety of integral equations and the methods of their solution.
• John E G Farina, in the review [',' J E G Farina, Review: Integral Equations, by B L Moiseiwitsch, The Mathematical Gazette 61 (418) (1977), 315.','6], writes:- .
• This book on integral equations is intended for students in the final year of an honours mathematics or mathematical physics course, but might also be useful to engineering students with a strong mathematical background.
• The second part examines Fourier series and Fourier and Laplace transforms, integral equations, wave motion, heat conduction, tensor analysis, special and general relativity, quantum theory, and variational principles.

77. Louis Nirenberg (1925-)
• Also in 1953, the first year in which his publications appear, he published three further papers: A strong maximum principle for parabolic equations; A maximum principle for a class of hyperbolic equations and applications to equations of mixed elliptic-hyperbolic type; and On nonlinear elliptic partial differential equations and Holder continuity.
• Some other highlights are his research on the regularity of free boundary problems with [David] Kinderlehrer and [Joel] Spuck, existence of smooth solutions of equations of Monge-Ampere type with [Luis] Caffarelli and Spuck, and singular sets for the Navier-Stokes equations with Caffarelli and [Robert] Kohn.
• His study of symmetric solutions of non-linear elliptic equations using moving plane methods with [Basilis] Gidas and [Wei Ming] Ni and later with [Henri] Berestycki, is an ingenious application of the maximum principle.
• He is quoted as saying [',' J Mawhin, Louis Nirenberg and Klaus Schmitt: The joy of differential equations, Electronic Journal of Differential Equations, Conference 15 (2007), 221-228.','5]:- .
• This is used in Chapters III and IV in the discussion of bifurcation theory (the highlight being a complete proof of Rabinowitz' global bifurcation theorem) and the solution of nonlinear partial differential equations (the highlight being the global theorem of Landesman and Lazer).
• Here is the first [',' J Mawhin, Louis Nirenberg and Klaus Schmitt: The joy of differential equations, Electronic Journal of Differential Equations, Conference 15 (2007), 221-228.','5]:- .
• The second quote related to an author's results he was describing [',' J Mawhin, Louis Nirenberg and Klaus Schmitt: The joy of differential equations, Electronic Journal of Differential Equations, Conference 15 (2007), 221-228.','5]:- .
• The nonlinear character of the equations is used in an essential way, indeed he obtains results because of the nonlinearity not despite it.
• for his work in partial differential equations.
• He was a plenary speaker at the International Congress of Mathematicians held in Stockholm in August 1962, giving the lecture Some Aspects of Linear and Nonlinear Partial Differential Equations.
• He shared the Prize of 350000 Swedish crowns with Vladimir Igorevich Arnold for their achievements in the field of non-linear differential equations.
• The equations are then called partial differential equations and again the most interesting ones are non-linear.
• As an example from geometry one can mention the problem to find a surface with given curvature and from physics studies of the equations for viscose fluids and concerning existence of free streamlines.
• The work of Louis Nirenberg has enormously influenced all areas of mathematics linked one way or another with partial differential equations: real and complex analysis, calculus of variations, differential geometry, continuum and fluid mechanics.
• Caffarelli mentions Nirenberg's areas of interest in partial differential equations: Regularity and solvability of elliptic equations of order 2n; the Minkowski problem and fully nonlinear equations; the theory of higher regularity for free boundary problems; and symmetry properties of solutions to invariant equations.
• His range of interest is very broad: differential equations, harmonic analysis, differential geometry, functional analysis, complex analysis, etc.
• striking and seminal contributions to the theory of nonlinear partial differential equations and its applications to geometric analysis.

78. Ovide Arino (1947-2003)
• Solutions periodiques d'equations differentielles a argument retarde.
• Oscillations autour d'un point stationnaire, conditions suffisantes de non-existence Ⓣ (1980); "Following a note by P Seguier the authors give some results on the non-existence of a nontrivial periodic solution to differential equations with delay, using mainly properties of monotonicity.
• Stabilite d'un ensemble ferme pour une equation differentielle a argument retarde Ⓣ (1978); "Our aim is to establish a local existence result for a differential equation with delay in a reflexive Banach space, with the hypothesis of weak continuity in the second member.
• Solutions oscillantes d'equations differentielles autonomes a retard Ⓣ (1978); "We show some results proving the existence, and specifying the behaviour, of solutions oscillating near a stationary point for some equations of the type x '(t) = L(xt) + N(xt) which have certain monotone and continuity properties.
• Comportement des solutions d'equations differentielles a retard dans un espace ordonne Ⓣ (1980); "Using vectorial Ljapunov functionals, we give here some results related to the behaviour at infinity of solutions of a differential equation with delay in an ordered Banach space." .
• Arino studied for a doctorate supervised by Maurice Gaultier and was awarded the degree in 1980 from the University of Bordeaux for his thesis Contributions a l'etude des comportements des solutions d'equations differentielles a retard par des methodes de monotonie et bifurcation Ⓣ.
• As can be seen from this work his interest was mainly in differential equations, mainly with delay, but later he became primarily involved with applications of these ideas to biomathematics, particularly population dynamics.
• His results in the field of delay differential equations stand out: oscillations, functional differential equations in infinite dimensional spaces, state-dependent delay differential equations.
• In the light of this theory a cell equation involving unequal division is investigated in great detail.

79. Blagoj Popov (1923-2014)
• His thesis was on differential equations.
• Those published in 1949-51 included: Sur la condition d'integrabilite de Karamata de l'equation de la balistique exterieure Ⓣ (Serbian) (1949); Contribution a la geometrie du triangle Ⓣ (Macedonian) (1949); Sur une condition d'integrabilite de d'Alembert relative a l'equation differentielle de la balistique Ⓣ (Macedonian) (1950); Sur une equation algebrique proposee par Pitoiset Ⓣ (1951); Sur une equation algebrique Ⓣ (Macedonian) (1951); On a property of the derivatives of orthogonal polynomials (1951); Factorization of an operator (Macedonian) (1951); and Remarque sur l'equation de Riccati Ⓣ (Macedonian) (1951).
• In 1952 he submitted his thesis Formation des criteriums de reductibilite des equations differentielles lineaires ayant des formes donnees a l'avance Ⓣ (Macedonian) and he was awarded the degree in 1953.
• "It will be of interest to me to become acquainted with methods of present research (in America) and an exchange of ideas." Dr Popov is the author of 35 publications on special functions and differential equations and has published a textbook on calculus.
• His research interests and numerous publications (more than 70) are in the areas such as functions of complex variables and algebraic calculus, and, in particular, in the field of differential equations and special functions related to them.
• He had the chance to specialize and develop himself as a scientist, and to play his pioneering role in Macedonia at the time when this field became particularly important for the applications of mathematics to Engineering and Physics; the time of the first electrotechniques (related to systems of linear differential equations), rocket techniques (differential equation with variable mass), nuclear energy problems (special functions and differential equations of mathematical physics), control theory, etc.
• Nowadays, looking back at the list of his publications, it appears that there is no kind of differential equation or special function that has not been studied by him! He had investigated: the equation of ballistics, the hypergeometric, Riccati, Legendre, confluent hypergeometric, Bessel, Weber, Hermite, Darboux, Whittaker, and Laplace differential equations; orthogonal polynomials, Legendre, Gegenbauer, Jacobi, Hermite, Laguerre, Bernoulli, Bessel, and Chebyshev polynomials, the associate spherical Legendre functions, the ultraspherical polynomials, the generalized Legendre and q-Appell polynomials.

80. Omar Khayyam (1048-1131)
• This problem in turn led Khayyam to solve the cubic equation x3 + 200x = 20x2 + 2000 and he found a positive root of this cubic by considering the intersection of a rectangular hyperbola and a circle.
• Khayyam also wrote that he hoped to give a full description of the solution of cubic equations in a later work [',' O Khayyam, A paper of Omar Khayyam, Scripta Math.
• Indeed Khayyam did produce such a work, the Treatise on Demonstration of Problems of Algebra which contained a complete classification of cubic equations with geometric solutions found by means of intersecting conic sections.
• In fact Khayyam gives an interesting historical account in which he claims that the Greeks had left nothing on the theory of cubic equations.
• Indeed, as Khayyam writes, the contributions by earlier writers such as al-Mahani and al-Khazin were to translate geometric problems into algebraic equations (something which was essentially impossible before the work of al-Khwarizmi).
• However, Khayyam himself seems to have been the first to conceive a general theory of cubic equations.
• Another achievement in the algebra text is Khayyam's realisation that a cubic equation can have more than one solution.
• He demonstrated the existence of equations having two solutions, but unfortunately he does not appear to have found that a cubic can have three solutions.
• Khayyam's construction for solving a cubic equation .

81. Erwin Schrödinger (1887-1961)
• In theoretical physics he studied analytical mechanics, applications of partial differential equations to dynamics, eigenvalue problems, Maxwell's equations and electromagnetic theory, optics, thermodynamics, and statistical mechanics.
• In mathematics he was taught calculus and algebra by Franz Mertens, function theory, differential equations and mathematical statistics by Wilhelm Wirtinger (whom he found uninspiring as a lecturer).
• One week later Schrodinger gave a seminar on de Broglie's work and a member of the audience, a student of Sommerfeld's, suggested that there should be a wave equation.
• Within a few weeks Schrodinger had found his wave equation.
• In its most general form, the time-dependent Schrodinger equation describes the time evolution of closed quantum physical systems as .
• The solution of the natural boundary value problem of this differential equation in wave mechanics is completely equivalent to the solution of Heisenberg's algebraic problem.
• I am simply fascinated by your [wave equation] theory and the wonderful new viewpoint it brings.
• Schrodinger's grave at Alpbach in Austria (Note the wave equation!) .

82. Neil Trudinger (1942-)
• in 1966 for his thesis Quasilinear Elliptical Partial Differential Equations in n Variables.
• First there is the paper On the Dirichlet problem for quasilinear uniformly elliptic equations in n variables in which he extended previous work by his supervisor David Gilbarg, Olga Ladyzhenskaya and others on the solvability of the classical Dirichlet problem in bounded domains for certain second order quasilinear uniformly elliptic equations.
• Secondly, in the paper The Dirichlet problem for nonuniformly elliptic equation he exploited the maximum principle to formulate general conditions for solvability of the Dirichlet problem for certain nonlinear elliptic equations.
• In another 1967 paper On Harnack type inequalities and their application to quasilinear elliptic equations Trudinger examines weak solutions, subsolutions and supersolutions of certain quasilinear second order differential equations.
• The book Elliptic partial differential equations of second order aimed to present (in the words of the authors):- .
• the systematic development of the general theory of second order quasilinear elliptic equations and of the linear theory required in the process.
• to the theory of quasilinear partial differential equations.
• It had two new chapters one of which examined strong solutions of linear elliptic equations, and the other was on fully nonlinear elliptic equations.
• The theory of nonlinear elliptic second order equations has continued to flourish during the last fifteen years and, in a brief epilogue to this volume, we signal some of the major advances.
• In recent years, members of the programme have solved major open problems in curvature flow, affine geometry and optimal transportation, using techniques from nonlinear partial differential equations.

83. Ray Vanstone (1933-2001)
• Examples are Synge's geometrization of mechanics, Riesz' approach to linear elliptic partial differential equations, and the well-known general theory of relativity of Einstein.
• Also in 1962 his paper The general static spherically symmetric solution of the "weak'' unified field equations was published and, in 1964, his paper The Hamilton-Jacobi equations for a relativistic charged particle appeared.
• In the problem of finding the motion of a classical particle one has the choice of dealing with a system of second order ordinary differential equations (Lagrange's equations) or a single first order partial differential equation (the Hamilton-Jacobi equation, henceforth referred to as the H-J equation).
• When these are obtainable, however, the method leads rapidly to the equations of the trajectories.

84. Ian Sneddon (1919-2000)
• It is a major text containing around 550 pages and is mainly concerned with applications which involve the solution of ordinary differential equations, and boundary value and initial value problems for partial differential equations.
• Sneddon's next text Elements of partial differential equations appeared the following year in 1957.
• The aim of this book is to present the elements of the theory of partial differential equations in a form suitable for the use of students and research workers whose main interest in the subject lies in finding solutions of particular equations rather than in the general theory.
• The applications of the methods are again the strength of the book which considers the use of partial differential equations in thermodynamics, stochastic processes, and birth and death processes for bacteria.
• The book deals with, among other topics, Laplace's equation, mixed boundary value problems, the wave equation, and the heat equation.

85. Qin Jiushao (1202-1261)
• There is a remarkable formula given in this Chapter which expresses the area of a figure as the root of an equation of degree 4.
• Again equations of high degree appear, one problem involving the solution of the equation of degree 10.
• Qin obtains the equation (really an equation of degree 5 in x2, where x2 is the diameter of the city):- .
• Throughout the text, in addition to the tenth degree equation above, Qin also reduces the solution of certain problems to a cubic or quartic equation which he solves by the standard Chinese method (namely that which today is called the Ruffini-Horner method).
• For example the following two equations .
• Qin also solves linear simultaneous equations, in particular the system .

86. Woolsey Johnson (1841-1927)
• It was during this year at Cambridge that he wrote his book A Treatise on Ordinary and Partial Differential Equations.
• In fairness to Johnson, the book G H Hardy is reviewing is a 1907 version of a book that Johnson did write over 20 years earlier! Here is a review of A Treatise on Ordinary and Partial Differential Equations which was published in the year the book was written [',' Anon, Review: A Treatise on Ordinary and Partial Differential Equations, by William Woolsey Johnson, Science 14 (350) (1889), 271.','1]:- .
• This treatise on differential equations is in continuation of the series of mathematical textbooks, by the same author, of which have already appeared the differential and integral calculus.
• Johnson published many notes and minor papers in The Analyst including: Bipolar Equations-Cartesian Ovals (1875); The Peaucellier Machine and Other Linkages (1875); Paradox for Students in Analytical Geometry (1875); On the Distribution of Primes (1875); Theory of Parallels (1876); On the Expression 00 (1876); Recent Results in the Study of Linkages (1876); Recent Results in the Study of Linkages [Continued] (1876); Note on Evaluation of Indeterminate Forms (1877); Classification of Plane Curves with Reference to Inversion (1877); Singular Solutions of Differential Equations of the First Order (1877); Pedal Curves (1877); Symmetrical Functions of the Sines of the Angles Included in the Expression a0 + 2k π/n (1879); Note on the Catenary (1879); New Notation for Anharmonic Ratios (1882); Note on Anharmonic Ratios (1883); and Circular Coordinates (1883).
• When The Analyst ceased publication and was replaced by the Annals of Mathematics, Johnson continued to publish there with papers such as: James Glaisher's factor tables and the distribution of primes (1884); The kinematical method of tangents (1885); On Singular Solutions of Differential Equations of the First Order (1887); On singular solutions of differential equations of the first order (1887); On the differential equation (1887); On Monge's solution of the non-integrable equation between three variables (1888); and On Gauss's method of substitution (1892).

87. Enrico Magenes (1923-2010)
• Sansone made important contributions to analysis, particularly with his studies of ordinary differential equations.
• The paper considers the problem of the existence of solutions of the differential equation in the title which pass through a given point and are tangent to a given curve.
• The first of these papers examines the values of λ for which the equation in the title, subject to certain boundary conditions, has a solution.
• Stampacchia and I wanted to know and make known in Italy the results of the school of Laurent Schwartz on distributions and on partial differential equations.
• Together they investigated inhomogeneous boundary problems for elliptic equations and inhomogeneous initial-boundary value problems for parabolic and hyperbolic evolution equations.
• If there are still people who feel that the subject of partial differential equations is "dirty" mathematics, this work should refute them once and for all.
• It is a work to be recommended to every serious student of partial differential equations and particularly to those who are fascinated by the manner in which modern functional analysis has aided and influenced their study.
• In a remarkable series of papers, followed and made complete in a three-volume book in cooperation with J L Lions (Nonhomogeneous Boundary Value Problems and Applications), he set the foundations for the modern treatment of partial differential equations, and in particular the ones mostly used in applications.
• After his death, students, friends and colleagues organised the conference 'Analysis and Numerics of Partial Differential Equations' in his memory at Pavia in November 2011.

88. Menahem Schiffer (1911-1997)
• They wrote the monograph Kernel functions and elliptic differential equations in mathematical physics (1953) tying together their joint work.
• In this book the authors collect their researches of the last few years on elliptic partial differential equations.
• The second part lays more stress on rigour, and treats fundamental solutions, reduction of boundary value problems to integral equations, orthonormal systems and kernel functions, eigenvalue problems associated with the kernels, variational theory of domain functions, comparison domains, basic existence theorems, and dependence of solutions on the boundary data or on the coefficients of the differential equation.
• The presentation is in an easy flowing style, and the material should prove to be a most useful guide to those interested in the more advanced theory of linear elliptic partial differential equations.
• Although the method yields in all cases first-order differential equations for the analytic arcs bounding the extremal domains, these equations will contain - except in some of the simpler problems - accessory parameters which are not known a priori and which have to be determined by additional considerations using the special features of the problem on hand.
• The paper concludes with a description of the author's method for obtaining a lower bound for the first eigenvalue of the Poincare-Fredholm integral equation in the case of a simply-connected domain bounded by an analytic curve.
• He was keen to apply his complex analysis results to mathematical physics, particularly making important contributions to the partial differential equations of hydrodynamics.
• All of the famous equations associated with that theory are derived here.

89. Ivan Georgievich Petrovsky (1901-1973)
• The 1928 paper deals with the Dirichlet problem for Laplace's equation and in the 1929 paper he solved a problem originally posed by Lebesgue.
• Also in 1951 he was appointed as Head of the Department of Differential Equations at the University.
• Petrovsky's main mathematical work was on the theory of partial differential equations, the topology of algebraic curves and surfaces, and probability.
• Petrovsky also worked on the boundary value problem for the heat equation and this was applied to both probability theory and work of Kolmogorov.
• Garding [',' O A Oleinik et al., International Conference on Differential Equations and Related Questions In honour of the 90th anniversary of the birth of Academician I G Petrovskii (1901-1973), Russian Math.
• Surveys 46 (6) (1991), 149-215.','32] spoke about three of Petrovsky's papers on partial differential equations:- .
• Apparently, Petrovskii was the first to use the Fourier transform to study higher-order equations with variable coefficients.
• He published a number of important textbooks: Lectures on the Theory of Ordinary Differential Equations (1939) (based on courses of lectures he gave at the universities of Moscow and Saratov); Lektsii po teorii integralnykh uravneny Ⓣ (1948), translated into German as Vorlesungen uber die Theorie der Integralgleichungen Ⓣ (1953) (based on courses of lectures he gave at the universities of Moscow); Lektsii ob uravneniakh s chastnymi proizvodnymi Ⓣ (1948), translated into English as Lectures in Partial Differential Equations (1954) and into German as Vorlesungen uber partielle Differential gleichungen Ⓣ (1955) (based on courses of lectures he gave at the universities of Moscow); and Lectures on Partial Differential Equations (1950) (based on courses of lectures he gave at the universities of Moscow).

90. Georgii Vasilovich Pfeiffer (1872-1946)
• When he returned to Kiev he was made head of the Department of Ordinary Differential Equations at the University.
• Pfeiffer's first research was on the problem of solving equations by radicals, and he next looked at algebraic geometry.
• Georgii Vasil'evich Pfeiffer (1872-1946), professor at Kiev University, is known as a specialist in the field of integration of differential equations and systems of partial differential equations.
• As this quote indicates, however, his most important contributions involve work on partial differential equations following on from the methods developed by Lie and Lagrange.
• some work of the Ukrainian mathematician G V Pfeiffer , showing how to find integrals of a general system of partial differential equations by using sequential complete systems instead of passing to Jacobian systems.
• Pfeiffer also constructed all the infinitesimal operators of a system of equations.
• For example, he published three papers in 1946: La reception et l'integration par la methode speciale des equations, systemes d'equations semi-Jacobiens, des equations, systemes d'equations semi-Jacobiens generalises aux derivees partielles du premier ordre de plusieurs fonctions inconnues Ⓣ; Sur les equations, systemes d'equations semi-jacobiens, semi-jacobiens generalises aux derivees partielles de premier ordre a plusieurs fonctions inconnues Ⓣ; and Sur les equations, systemes d'equations semi-mixtes aux derivees partielles du premier ordre a plusieurs fonctions inconnues Ⓣ.
• As the title indicates, the paper is concerned with a special method for solving semi-Jacobian systems of partial differential equations.
• Such a system arises from a linear partial differential equation of the first order containing one or more parameters whose elimination leads to the Jacobian system of equations which are nonlinear.
• The author sketches two rules for integration of systems of "semi-mixed'' partial differential equations of the first order with several unknown functions.
• The author sketches two ways of applying his method of integration [first published in 1923] to systems of generalized semi-Jacobian equations of the first order with several unknown functions.
• He also published books such as his 346-page 1937 book Integration of differential equations.
• He also used his language skills to translate books such as the 1891 French text by Edouard Goursat Lecons sur l'integration des equations aux derivees partielles du premier ordre Ⓣ which appeared in Ukrainian in 1940.

91. Anna Johnson Wheeler (1883-1966)
• The records show that Anna studied Algebra and Trigonometry in 1899-1900, Modern Geometry, the Theory of Equations, and Solid Analytical Geometry in 1900-1901, Calculus, Analytical mechanics and Plane Analytical Geometry in 1901-02, and the Theory of Substitutions and Potential, Partial Differential Equations and Fourier Series, and Differential Equations in 1902-03.
• After winning a scholarship to study for her master's degree at the University of Iowa, she was awarded the degree for a thesis The extension of Galois theory to linear differential equations in 1904.
• After returning to the United States in August 1907, where her husband was by now Dean of Engineering in South Dakota, she taught courses in the theory of functions and differential equations.
• in 1910 for her thesis Biorthogonal Systems of Functions with Applications to the Theory of Integral Equations being the one written originally at Gottingen.
• She took various courses at Chicago: General analysis; Periodic Orbits; Theory of Numbers; Integral Equations; Modern Analysis applied to celestial Mechanics; and Theory of Algebraic Numbers.
• Anna Pell had published two papers in the Bulletin of the American Mathematical Society in 1909-10, namely On an integral equation with an adjoined condition and Existence theorems for certain unsymmetric kernels.
• While at this College she published Non-homogeneous linear equations in infinitely many unknowns (1914) and (with Ruth L Gordon) The modified remainders obtained in finding the highest common factor of two polynomials (1916).
• Under his guidance she worked on integral equations studying infinite dimensional linear spaces.
• As an example of one of the papers she wrote while on the Faculty at Bryn Mawr, we mention Linear Ordinary Self-Adjoint Differential Equations of the Second Order (1927).
• In 1914 Lichtenstein made connection, without the intermediary of the theory of integral equations, between the theory of linear differential systems of the second order and the theory of linear equations in infinitely many unknowns.

92. Yurii Sokolov (1896-1971)
• He also worked on functional equations and on such practical problems as the filtration of groundwater.
• Other applications include On the determination of dynamic pull in shaft-lifting cables (Ukrainian) (1955) and On approximate solution of the basic equation of the dynamics of a hoisting cable (Ukrainian) (1955).
• One of the topics which will always be associated with Sokolov's name is his method for finding approximate solutions to differential and integral equations.
• Examples of his papers on this topic are On a method of approximate solution of linear integral and differential equations (Ukrainian) (1955), Sur la methode du moyennage des corrections fonctionnelles Ⓣ (Russian) (1957), Sur l'application de la methode des corrections fonctionnelles moyennes aux equations integrales non lineaires Ⓣ (Russian) (1957), On a method of approximate solution of systems of linear integral equations (Russian) (1961), On a method of approximate solution of systems of nonlinear integral equations with constant limits (Russian) (1963), and On sufficient tests for the convergence of the method of averaging of functional corrections (Russian) (1965).
• This basic approach is developed by the author and applied to the approximate solution of Fredholm and Volterra-type integral equations of the second kind, to their nonlinear counterparts, to integral equations of mixed type, to linear and nonlinear one-dimensional boundary value problems, to initial-value problems in ordinary differential equations and to certain elliptic, hyperbolic and parabolic equations.
• The first part of Sokolov's book discusses applications of his method to problems which can be modelled by linear integral equations with constant limits.
• The next three parts look first at problems which can be modelled by nonlinear integral equations with constant limits and then extend the analysis to the situation where the upper limit is variable.
• In the final part Sokolov examines applications of his method to integral equations of mixed type, then in a number of appendices he presents some generalisations of the method.

93. Richard Schoen (1950-)
• Justin Corvino and Daniel Pollack describe the advances made by Schoen at this time [',' J Corvino and D Pollack, Scalar Curvature and the Einstein Constraint Equations.','1]:- .
• Not only did their work employ serious tools of geometric analysis, including partial differential equations and geometric measure theory, to resolve a question motivated by gravitational physics, but they also established a link between the positivity of the mass of an isolated gravitational system and the relationship between positive scalar curvature and topology, a topic of interest to a broad range of mathematicians.
• In the early eighties, Schoen brought the Positive Mass Theorem to bear on the resolution of the famous Yamabe problem, providing more evidence to support the development of the mathematical theory of the constraint equations, and inspiring many others to do so.
• At the Berkeley Congress he gave the lecture New Developments in the Theory of Geometric Partial Differential Equations.
• The author surveys recent work on nonlinear elliptic partial differential equations which arise from geometric sources, concentrating especially on the Yamabe problem and the theory of harmonic mappings.
• For the former, an outline is given of the recent solution of Yamabe's conjecture (that every metric on a compact manifold is pointwise conformally equivalent to one with constant scalar curvature), including the use of the positive mass theorem and a discussion of regularity of weak solutions of Yamabe's equation.
• for his work on the application of partial differential equations to differential geometry, in particular his completion of the solution to the Yamabe Problem in "Conformal deformation of a Riemannian metric to constant scalar curvature".
• Schoen, 40, continues his research in differential geometry, nonlinear partial differential equations and the calculus of variations.
• The main topics are differential equations on a manifold and the relation between curvature and topology of a Riemannian manifold.
• He serves on the editorial boards of: the Journal of Differential Geometry, Communications in Analysis and Geometry, Communications in Partial Differential Equations, Calculus of Variations and Partial Differential Equations, and Communications in Contemporary Mathematics.
• We end this biography by quoting from [',' J Corvino and D Pollack, Scalar Curvature and the Einstein Constraint Equations.','1] written by two mathematicians who received their doctorates with Schoen as advisor:- .
• His research has fundamentally shaped geometric analysis, and his results form many cornerstones within geometry, partial differential equations and general relativity.

94. Albert Girard (1595-1632)
• Gray Funkhouser writes [',' H Gray Funkhouser, A Short Account of the History of Symmetric Functions of Roots of Equations, Amer.
• The first man who really has a place in the history of symmetric functions of roots of equations, a man who for clearness and grasp of material at hand in not only this topic but also in other phases of algebra could well hold his place a century later was Albert Girard ..
• He gives an example of the equation (which we write in modern notation) .
• then in an equation of any degree .
• He was the first who spoke of the imaginary roots, and understood that every equation might have as many roots real and imaginary, and no more, as there are units in the index of the highest power.
• He was the first who discovered the rules for summing the powers of the roots of any equation.
• We should also mention his iterative approach to solving equations [',' J Itard, Biography in Dictionary of Scientific Biography (New York 1970-1990).
• With the aid of trigonometric tables Girard solved equations of the third degree having three real roots.

95. Brahmagupta (598-670)
• Brahmagupta developed some algebraic notation and presents methods to solve quardatic equations.
• He presents methods to solve indeterminate equations of the form ax + c = by.
• Brahmagupta perhaps used the method of continued fractions to find the integral solution of an indeterminate equation of the type ax + c = by.
• Brahmagupta also solves quadratic indeterminate equations of the type ax2 + c = y2 and ax2 - c = y2.
• For the equation 11x2 + 1 = y2 Brahmagupta obtained the solutions (x, y) = (3, 10), (161/5, 534/5), ..
• Pell's equation .
• History Topics: Quadratic, cubic and quartic equations .
• History Topics: Pell's equation .

96. Cyrus Colton MacDuffee (1895-1961)
• While at Princeton he published a number of papers including: On transformable systems and covariants of algebraic forms (1923), On covariants of linear algebras (1924), The nullity of a matrix relative to a field (1925) and On the complete independence of the functional equations of involution (1925).
• This was the first of four classic books that MacDuffee wrote, the other three being An introduction to abstract algebra (1940), Vectors and matrices (1943) and Theory of equations (1954).
• The course which I have been giving at Wisconsin for the last couple of years is still entitled the Theory of Equations, but might more properly be called the Theory of Polynomials.
• This approach seems to unify the somewhat scattered topics in the theory of equations, and to give a deeper insight into the subject which is particularly valuable to those who go on in algebra and to those who contemplate teaching algebra.
• After this bit of number theory it is easy to attack the problem of finding the integral solutions of an equation having integral coefficients, and the rational solutions of an equation having rational coefficients.
• Let us consider for a moment the theorem that if an equation with integral coefficients has a rational solution, when this solution is expressed in lowest terms the numerator is a divisor of the constant term of the equation.

• While an undergraduate he had already published some important papers (all in Russian): Simple examples of unsolvable canonical calculi (1967), Simple examples of unsolvable associative calculi (1967), Arithmetic representations of powers (1968), A connection between systems of word and length equations and Hilbert's tenth problem (1968), and Two reductions of Hilbert's tenth problem (1968).
• Devise a process according to which it can be determined by a finite number of operations whether a given polynomial equation with integer coefficients in any number of unknowns is solvable in rational integers.
• Does there exist an algorithm to determine whether a Diophantine equation has a solution in natural numbers? .
• In 1934 Thoralf Skolem showed that to solve Hilbert's Tenth Problem, it is sufficient to consider only Diophantine equations of total degree four.
• It was connected with the special form of Pell's equation.
• In this thesis, as well as giving a simplified proof that no algorithm exists to determine whether Diophantine equations have integer solutions, he gave a Diophantine representation of a wide class of natural number sequences produced by linear recurrence relations.
• His paper Existential arithmetization of Diophantine equations (2009) continues work related to Hilbert's Tenth problem and, as Alexandra Shlapentokh writes:- .
• continues his investigation of coding methods by introducing a coding scheme which, among other things, leads to the elimination of bounded quantifiers, arithmetization of Turing machines, and a much simplified construction of a universal Diophantine equation.

98. Tosio Kato (1917-1999)
• II in 1950, and Note on Schwinger's variational method, On the existence of solutions of the helium wave equation, Upper and lower bounds of scattering phases and Fundamental properties of Hamiltonian operators of Schrodinger type in 1951.
• The course covered, thoroughly but efficiently, most of the standard material from the theory of functions through partial differential equations.
• In 1962 he introduced new powerful techniques for studying the partial differential equations of incompressible fluid mechanics, the Navier-Stokes equations.
• In 1983 he discovered the "Kato smoothing" effect while studying the initial-value problem associated with the Korteweg-de Vries equation, which was originally introduced to model the propagation of shallow water waves.
• Another contribution to this area was On the Korteweg-de Vries equation where, in Kato's words from the paper:- .
• Existence, uniqueness, and continuous dependence on the initial data are proved for the local (in time) solution of the (generalized) Korteweg-de Vries equation on the real line ..
• He lectured on Abstract differential equations and nonlinear mixed problems.

99. Cathleen Morawetz (1923-2017)
• In a series of three significant papers in the late 1950s, Cathleen Morawetz used functional analysis coupled with ingenious new estimates for an equation of mixed type, i.e.
• with both elliptic and hyperbolic regions, to prove a striking new theorem for boundary value problems for partial differential equations.
• During the 1970s she extended this work to examine other solutions to the wave equation.
• She proved many important results relating to the non-linear wave equation.
• for pioneering advances in partial differential equations and wave propagation resulting in applications to aerodynamics, acoustics and optics.
• In addition to her deep contributions to partial differential equations, transonic flow, and other areas of applied mathematics, she provided guidance and inspiration to colleagues and students alike.
• .for her deep and influential work in partial differential equations, most notably in the study of shock waves, transonic flow, scattering theory, and conformally invariant estimates for the wave equation.

100. Aleksei Krylov (1863-1945)
• There he was taught advanced mathematics by Aleksandr Nikolaevich Korkin, a student of Chebyshev, who was an expert in partial differential equations.
• In 1904 he constructed a mechanical integrator to solve ordinary differential equations, being the first in Russia to make such an instrument.
• He studied the acceleration of convergence of Fourier series in a paper in 1912, and studied the approximate solutions to differential equations in a paper published in 1917.
• In 1931 he found a new method of solving the secular equation determining the frequency of vibrations in mechanical systems which is better than methods due to Lagrange, Laplace, Jacobi and Le Verrier.
• This paper On the numerical solution of the equation by which, in technical matters, frequencies of small oscillations of material systems are determined deals with eigenvalue problems.
• It is clear that, if for k = 2 and k = 3 it is easy to compose this [secular] equation, then for k = 4 the laying-out becomes cumbersome, and for values k more than 5 this is completely unrealisable in a direct way.
• is to present simple methods of composition of the secular equation in the developed form, after which, its solution, i.e.
• The first edition of On Some Differential Equations of Mathematical Physics Having Application to Technical Problems appeared in 1913, the second edition in 1932, and the fourth appeared in 1948 as part of Krylov's collected works.

101. Yvonne Bruhat (1923-)
• She dedicated the book General Relativity and the Einstein Equations (2009) she wrote many years later to:- .
• She was awarded her doctorate in 1951 for her thesis Theoreme d'existence pour certains systemes d'equations aux derivees partielles non lineaires Ⓣ.
• Further papers followed: Theoreme d'existence pour les equations de la gravitation einsteinienne dans le cas non analytique Ⓣ (1950); Un theoreme d'existence sur les systemes d'equations aux derivees partielles quasi lineaires Ⓣ (1950); and Theoremes d'existence et d'unicite pour les equations de la theorie unitaire de Jordan-Thiry Ⓣ (1951).
• One has to face difficult nonlinear partial differential equations in Einstein's theory of gravity.
• Of very great significance is that Yvonne Bruhat's analysis enabled her to prove rigorously for the first time local-in-time existence and uniqueness of solutions of the Einstein equations.
• Ondes Asymptotiques et Approchees pour des Systemes d'Equations aux Derivees Partielles non Lineaires Ⓣ, published in 1969, gives a method for constructing asymptotic and approximate wave solutions about a given solution for nonlinear systems of partial differential equations.
• Global Solutions of the Problem of Constraints on a Closed Manifold, published in 1973, shows that the existence of global solutions of the constraint equations of general relativity on a closed manifold depend on subtle properties of the manifold.
• Bruhat gave courses at the University of Paris to students taking the Master of Mathematics degree which prepared them for the practical use of distributions in the partial differential equations of theoretical physics.
• They have succeeded in gathering in one volume the mathematical infrastructure of modern mathematical physics, which includes the theories of differentiable manifolds and global analysis, Riemannian and Kahlerian geometry, Lie groups, fibre bundles and their connections, characteristic classes and index theorems, distributions, and partial differential equations.
• The original book already had a number of interesting applications, such as the Schrodinger equation, soap bubbles, electromagnetism, shocks, gravity, Hamiltonian systems, monopoles, spinors, degree theory applied to PDE, Wiener measure, etc.
• Her latest book, General relativity and the Einstein equations was published in 2009.
• As the title indicates, the emphasis is on the mathematical properties of the Einstein equations, in particular the local and global existence theorems of the initial value problem.
• for their separate as well as joint work in proving the existence and uniqueness of solutions to Einstein's gravitational field equations so as to improve numerical solution procedures with relevance to realistic physical solutions.

102. Balthasar van der Pol (1889-1959)
• even in mathematics, his papers covered number theory, special functions, operational calculus and nonlinear differential equations.
• Of course, to most mathematicians the name of van der Pol is associated with the differential equation which now bears his name.
• This equation first appeared in his article On relaxation oscillation published in the Philosophical Magazine in 1926.
• 35 (1960), 367-376.','4], [',' Ya A Matviishin, The investigations of B van der Pol in the theory of nonlinear oscillations (Russian), Application of asymptotic methods in the theory of nonlinear differential equations (Russian) (Akad.
• We explain the history of the development of the equation carrying his name, and also the origins of the method of finding the first approximation to the solution of this equation (the method of slowly varying coefficients).
• Van der Pol did much to popularize his subject; he was an engaging lecturer, and often took the opportunity of bringing together phenomena over a wide field of science which could be elucidated by a single mathematical relation such as the equation for relaxation oscillations.
• In fact van der Pol corresponded with Nikolai Mitrofanovich Krylov about the theory of nonlinear oscillations; a letter sent by van der Pol to Krylov is published in [',' Ya A Matviishin, The investigations of B van der Pol in the theory of nonlinear oscillations (Russian), Application of asymptotic methods in the theory of nonlinear differential equations (Russian) (Akad.

103. Julia Bowman Robinson (1919-1985)
• Robinson was awarded a doctorate in 1948 and that same year started work on Hilbert's Tenth Problem: find an effective way to determine whether a Diophantine equation is soluble.
• Hilbert in 1900 posed the problem of finding a method for solving Diophantine equations as the 10th problem on his famous list of 23 problems which he believed should be the major challenges for mathematical research this century.
• Now you are going to ask how could he be sure? He couldn't check each possible method and maybe there were very involved methods that didn't seem to have anything to do with Diophantine equations but still worked.
• The method of proof is based on the fact that there is a Diophantine equation say P(x,y,z,..
• In 1971 at a conference in Bucharest Robinson gave a lecture Solving diophantine equations in which she set the agenda for continuing to study Diophantine equations following the negative solution to Hilbert's Tenth Problem problem.
• Instead of asking whether a given Diophantine equation has a solution, ask "for what equations do known methods yield the answer?" .

104. Scipione del Ferro (1465-1526)
• In one sense he is well known, for his role in solving cubic equations is explained in almost every general work on the history of mathematics ever written, and yet, surprisingly, his name remains relatively unknown.
• The outstanding problem which del Ferro solved was to find a formula to solve a cubic equation similar to the formula which had been known since the time of the Babylonians for solving quadratic equations.
• There has been much conjecture as to whether del Ferro came to work on the solution to cubic equations as a result of a visit which Pacioli made to Bologna.
• It is not known whether the two discussed the algebraic solution of cubic equations, but certainly Pacioli had included this topic in his famous treatise the Summa which he had published seven years earlier.
• Four years ago when Cardano was going to Florence and I accompanied him, we saw at Bologna Hannibal della Nave, a clever and humane man who showed us a little book in the hand of Scipione del Ferro, his father-in-law, written a long time ago, in which that discovery [solution of cubic equations] was elegantly and learnedly presented.
• Dal Ferro's rule for the solution of cubic equations.
• The manuscript gives a method of solution which is applied to the equation 3x3 + 18x = 60.
• History Topics: Quadratic, cubic and quartic equations .

105. Norrie Everitt (1924-2011)
• Everitt was awarded a DPhil in 1955 for his thesis Eigenfunction Expansions Associated with Fourth-Order Differential Equations.
• A paper based on the results of his thesis was The Sturm-Liouville problem for fourth-order differential equations (1957).
• In this paper I consider the direct extension to fourth-order ordinary differential equations of the analysis of the Sturm-Liouville problem given in his book 'Eigenfunction expansions associated with second-order differential equations' (Oxford, 1946) by E C Titchmarsh.
• This type of problem has been considered, for general-order equations, by many writers [see in particular G D Birkhoff, 'Boundary-value and expansion problems of ordinary differential equations' (1908) and J Tamarkin, 'Some general problems of the theory of ordinary linear differential equations and expansion of an arbitrary function in a series of fundamental functions' (1927)].
• Here we consider some of the explicit constructions for the eigenfunctions; the fact that equations of the fourth and higher order are occurring in mathematical physics suggests that such information might be useful.
• The method can be at once extended to equations of higher order and to more general boundary conditions than I consider here.
• Everitt published papers such as Some properties of Gram matrices and determinants (1958), A note on positive definite matrices (1958), Integrable-square solutions of ordinary differential equations (1959), On a generalization of Bessel functions and a resulting class of Fourier kernels (1959), On the Holder inequality (1961), Self-adjoint boundary value problems on finite intervals (1962), Integrable-square solutions of ordinary differential equations.
• II (1962), Two theorems in matrix theory (1962) and Fourth order singular differential equations (1962).
• One of his most significant contributions was the running of conferences on the 'Theory of Ordinary and Partial Differential Equations'.
• These Proceedings form a record of the lectures delivered at the Conference on the Theory of Ordinary and Partial Differential Equations held at the University of Dundee, Scotland during the four days 28 to 31 March 1972.
• The success of this conference led to it becoming the first in a series, and in 1978 the fifth 'Ordinary and Partial Differential Equations Conference' was held in Dundee with Everitt as the sole editor of the Proceedings.
• These Proceedings form a record of the plenary lectures delivered at the fifth Conference on Ordinary and Partial Differential Equations which was held at the University of Dundee, Scotland, UK during the period of three days Wednesday to Friday 29 to 31 March 1978.
• The Conference was held as a tribute to his memory and to the outstanding and distinguished contribution he had made to mathematical analysis and differential equations.
• With this monograph Everitt and Markus have produced a major advance in our understanding of the structure of self-adjoint boundary conditions for regular and singular linear ordinary differential equations of arbitrary order and with arbitrary deficiency index.
• In the case of finite dimensional complex symplectic spaces it was shown that the corresponding symplectic algebra is important for the description and classification of all self-adjoint boundary value problems for (linear) ordinary differential equations on a real interval.
• The conference "Spectral analysis and differential equations, A memorial meeting to mark the life and work ofn Professor W N Everitt" was held at the University of Cardiff on the 15-17 May 2014.
• a distinguished expert in the field of spectral analysis and differential equations, was a widely acknowledged authority on the spectral theory of differential equations, and inequalities.

106. Leon Lichtenstein (1878-1933)
• He did pioneering work in potential theory, integral equations, calculus of variations, differential equations and hydrodynamics.
• [Lichtenstein] made important contributions to the theory of partial differential equations, and the calculus of variations.
• The so-called "Schauder bounds" in the theory of elliptic differential equations can already be found quite precisely, for the two-dimensional case, in Lichtenstein's encyclopaedia articles.
• His tracing back of a class of integro-differential equations to a system of integral equations was of far reaching importance.
• By observing the ramification near any given equilibrium figure, which in contrast to Lyapunov's studies does not have to be an ellipsoid, he managed to advance a new integro-differential equation and to work out more clearly the basic ideas of ramification.
• For the author, the fundamental problem of hydrodynamics is the integration of certain systems of partial differential equations with assigned boundary conditions, and he calls to his aid all the resources of modern mathematics.
• It is not until we reach page 290 that the equations of motion are derived.
• Since he presupposes on the part of his readers a familiarity with the theory of the Newtonian potential function and of integral equations, together with a good grasp of other branches of analysis, geometry, and celestial mechanics, the book is not easy to read, but the results are so significant that it should be carefully studied by everyone who is seriously interested in the mathematical treatment of the problem of figures of equilibrium of rotating fluid bodies.
• He was glad to receive an invitation to teach for one trimester at the Jan Kazimierz University in Lwow [now the Ivan Franko University of Lviv] in 1930, where his lectures were on the theory of integral and integro-differential equations.

107. Yakov Davydovich Tamarkin (1888-1945)
• Tamarkin maintained his close friendship and academic collaboration with Friedmann and by 1908 the two were attending lectures by Steklov on partial differential equations.
• I proposed to Tamarkin that he think about the asymptotic solution of differential equations (i.e.
• and then submitted his thesis in 1917 on boundary value problems for linear differential equations.
• It was published in English in Mathematische Zeitschrift in 1928 as Some general problems of the theory of ordinary linear differential equations and expansion of an arbitrary function in series of fundamental functions.
• His research during this period continued on boundary value problems, but also included advances in mathematical physics, differential equations, and approximations.
• Five papers were published in these journals in 1926 and 1927: On Laplace's integral equations; On Volterra's integro-functional equation; A new proof of Parseval's identity for trigonometric functions; On Fredholm's integral equations, whose kernels are analytic in a parameter; and The notion of the Green's function in the theory of integro-differential equations.
• For example they published: On the summability of Fourier series (two papers), On a theorem of Hahn-Steinhaus, On a theorem of Paley and Wiener, On the theory of linear integral equations.
• The problem of moments is the theory of an infinite system of integral equations under various hypotheses.

108. Yurii Alekseevich Mitropolskii (1917-2008)
• Mitropolskii has made major contributions to the theory of oscillations and nonlinear mechanics as well as the qualitative theory of differential equations.
• Using a method of successive substitutes, he constructed a general solution for a system of nonlinear equations and studied its behaviour in the neighbourhood of the quasi-periodic solution.
• the creation and mathematical justification of algorithms for constructing asymptotic expansions for non-linear differential equations describing non-stationary oscillatory processes; .
• the investigation of systems of non-linear differential equations describing oscillatory processes in gyroscopic systems and strongly non-linear systems; .
• the development of the averaging method for equations with slowly varying parameters, as well as for equations with non-differentiable and discontinuous right-hand sides, for equations with delayed argument, for equations with random perturbations, and for partial differential equations and equations in functional spaces; .
• the development of the theory of reducibility in linear differential equations with quasi-periodic coefficients, and other equations.
• This work was to lead to further advances by the Kiev school, in particular they applied asymptotic methods to partial and functional differential equations.
• Asymptotic solutions of differential equations are worked out in great detail, the author always being willing to go the second mile with the reader in obtaining the inherently complicated formulas that arise.
• We give various algorithms, schemes and rules for constructing approximate solutions of equations with small and large parameters, and obtain examples which in many cases graphically illustrate the effectiveness of the method of averaging and the breadth of its application to various problems which are, at first glance, very disparate.
• Among the many co-authored works we mention Lectures on the application of asymptotic methods to the solution of partial differential equations (1968) co-authored with his former student Boris Illich Moseenkov, Lectures on the methods of integral manifolds (1968) co-authored with his former student Olga Borisovna Lykova, Lectures on the theory of oscillation of systems with lag (1969) co-authored with his former student Dmitrii Ivanovich Martynyuk, Asymptotic solutions of partial differential equations (1976) co-authored with his former student Boris Illich Moseenkov, Periodic and quasiperiodic oscillations of systems with lag (1979) also co-authored with D I Martynyuk, Mathematical justification of asymptotic methods of nonlinear mechanics (1983) co-authored with his former student Grigorii Petrovich Khoma, Group-theoretic approach in asymptotic methods of nonlinear mechanics (1988) co-authored with his former student Aleksey Konstantinovich Lopatin, and Asymptotic methods for investigating quasiwave equations of hyperbolic type (1991) co-authored with his former students G P Khoma and Miron Ivanovich Gromyak.
• Some of these were Ukrainian journals such as the differential equations journal Differentsial'nye Uravneniya, while others were international journals such as the International Journal of Nonlinear Sciences and Numerical Simulations, the journal Nonlinear Analysis, the journal Nonlinear Dynamics, and the International Journal of Nonlinear Mechanics.
• for his outstanding achievements in the theory of nonlinear differential equations and nonlinear oscillations.

109. Shing-Tung Yau (1949-)
• Yau was awarded a Fields Medal in 1982 for his contributions to partial differential equations, to the Calabi conjecture in algebraic geometry, to the positive mass conjecture of general relativity theory, and to real and complex Monge-Ampere equations.
• S-T Yau has done extremely deep and powerful work in differential geometry and partial differential equations.
• The analytic problem is that of proving the existence of a solution of a highly nonlinear (complex Monge-Ampere ) differential equation.
• .for his work in nonlinear partial differential equations, his contributions to the topology of differentiable manifolds, and for his work on the complex Monge-Ampere equation on compact complex manifolds.
• As a result of Yau's work over the past twenty years, the role and understanding of basic partial differential equations in geometry has changed and expanded enormously within the field of mathematics.
• His work has had, and will continue to have, a great impact on areas of mathematics and physics as diverse as topology, algebraic geometry, representation theory, and general relativity as well as differential geometry and partial differential equations.

110. Joseph-Louis Lagrange (1736-1813)
• He solved the resulting system of n+1 differential equations, then let n tend to infinity to obtain the same functional solution as Euler had done.
• In papers which were published in the third volume, Lagrange studied the integration of differential equations and made various applications to topics such as fluid mechanics (where he introduced the Lagrangian function).
• Also contained are methods to solve systems of linear differential equations which used the characteristic value of a linear substitution for the first time.
• In 1770 he also presented his important work Reflexions sur la resolution algebrique des equations Ⓣ which made a fundamental investigation of why equations of degrees up to 4 could be solved by radicals.
• The paper is the first to consider the roots of an equation as abstract quantities rather than having numerical values.
• The Mecanique analytique summarised all the work done in the field of mechanics since the time of Newton and is notable for its use of the theory of differential equations.
• Extract of Reflexions sur la resolution algebrique des equations from his collected works (1869) .
• History Topics: Pell's equation .

111. John Walsh (1786-1847)
• The equation of a curve transformed as above Mr Walsh calls its 'partial equation'.
• Memoir on the Invention of Partial Equations; The Theory of Partial Functions; Irish Manufactures: A New Method of Tangents; An Introduction to the Geometry of the Sphere, Pyramid and Solid Angles; General Principles of the Theory of Sound; The Normal Diameter in Curves; The Problem of Double Tangency; The Geometric Base; The Theoretic Solution of Algebraic Equations of the Higher Orders.
• Thus, in a page headed Cubic Equations, he writes the name of Cardan opposite to a well-known algebraic solution, that of Walsh opposite to the same result put under another and less convenient form, and below these he gives a formula headed For a Complete Cubic by Walsh only.
• Discovered the general solution of numerical equations of the fifth degree at 114 Evergreen Street, at the Cross of Evergreen, Cork, at nine o'clock in the forenoon of July 7th, 1844; exactly twenty-two years after the invention of the Geometry of Partial Equations, and the expulsion of the differential calculus from Mathematical Science.
• And the falsehood of the offspring of that method, namely, the no less celebrated doctrine of fluxions, differentials, limits, etc., the boast and glory of England, France and Germany, demonstrated by the great invention of the geometry of partial equations which has superseded them, at least in my hands, and indefinitely surpassed the old system in power.

112. Christoff Rudolff (1499-1543)
• The first of these gives methods for solving linear and quadratic equations.
• Earlier works on solving equations had presented the reader with 24 different cases but Rudolff reduces this to 8 cases.
• In looking at the case of a quadratic of the form ax2 + b = cx he believed at first that there was only one solution to this equation which will solve the original problem, but he later recognised his error and realised that such equations have two solutions.
• The second chapter is again concerned with solving equations and presents rules for solving them.
• If there are more unknowns than equations, the problem is considered indeterminate.
• Rudolff was aware of the double root of the equation ax2 + b = cx and gave all the solutions to indeterminate first-degree equations.

113. Chike Obi (1921-2008)
• advisors were Mary Lucy Cartwright and John Edensor Littlewood who were working closely together on problems relating to differential equations.
• Obi submitted his first paper Subharmonic solutions of non-linear differential equations of the second order to the Journal of the London Mathematical Society in 1949 and it was published in 1950.
• He was awarded his doctorate in 1950 for his thesis Periodic Solutions of Non-linear Differential Equations of Second Order.
• The main results of his thesis were published in Periodic Solutions of Non-linear Differential Equations of Second Order parts IV and V appearing as two consecutive papers in Volume 47 of the Proceedings of the Cambridge Philosophical Society in 1951.
• In 1953, in addition to the book Our Struggle, Obi published two mathematical papers, both in Volume 28 of the Journal of the London Mathematical Society, namely Periodic solutions of non-linear differential equations of order 2n and A non-linear differential equation of the second order with periodic solutions whose associated limit cycles are algebraic curves.
• On many occasions, he would come straight from Lagos where he was a parliamentarian to give us lectures in Real Analysis and Differential Equations.
• An existence theorem for periodic oscillations of equations of the second order which appeared in the Proceedings of the Cambridge Philosophical Society in 1974.
• Between that time and when other offices opened, he solved his Differential Equations.
• The International Centre for Theoretical Physics Prize in honour of Sigvard Eklund (Sweden), Director General Emeritus of the IAEA (International Atomic Energy Agency, Vienna, Austria), in the field of Mathematics, was awarded to Chike Obi, University of Lagos, Nigeria, for significant contributions in the study of nonlinear ordinary differential equations with several parameters for which he established numerous results on the existence, number some analytic expressions of harmonic, subharmonic or uniformly almost periodic solutions.

114. James Serrin (1926-2012)
• In the years 1948 to 1950, James Serrin had the unique opportunity of attending lecture courses on elliptic differential equations given by Professors Eberhard Hopf and David Gilbarg at Indiana University.
• In addition to his work on hydrodynamics, he also began publishing very significant results on elliptic differential equations with papers such as On the Phragmen-Lindelof theorem for elliptic partial differential equations (1954), On the Harnack inequality for linear elliptic equations (1956) and (with David Gilbarg) On isolated singularities of solutions of second order linear elliptic equations (1956).
• The period 1963-1964 highlights the full maturity of Jim Serrin's thought, in particular in mastering the art of well adapted test functions for studying general quasilinear equations.
• It is during that period that his two articles ['Local behavior of solutions of quasi-linear equations' (1964) and 'Isolated singularities of solutions of quasi-linear equations' (1965)] on isolated singularities were published in 'Acta Mathematica'.
• The climax of this work is his famous article 'The problem of Dirichlet for quasilinear differentials equations with many independent variables', published in London in 1969 in the 'Philosophical Transactions of the Royal Society'.
• for his fundamental contributions to the theory of nonlinear partial differential equations, especially his work on existence and regularity theory for nonlinear elliptic equations, and applications of his work to the theory of minimal surfaces in higher dimensions.
• The maximum principle enables us to obtain information about solutions of differential equations and inequalities without any explicit knowledge of the solutions themselves, and thus can be a valuable tool in scientific research.
• The maximum principle moreover occurs in so many places and in such varied forms that anyone learning about it becomes acquainted with the classically important partial differential equations and, at the same time, discovers the reason for their importance.
• Since its first applications in the study of the Laplace and linear elliptic operators in general, the maximum principle has found a wide range of applications in nonlinear partial differential equations and inequalities, including equations involving the celebrated p-Laplace operator.
• He has served on the editorial boards of many major journals including the Archive for Rational Mechanics and Analysis, the Journal of Differential Equations, Communications in Partial Differential Equations, the Bulletin of the American Mathematical Society, Rendiconti Circolo Matematico di Palermo, Asymptotic Analysis, Differential and Integral Equations, Communications in Applied Analysis, and Advances in Differential Equations.

115. Terence Tao (1975-)
• for his contributions to partial differential equations, combinatorics, harmonic analysis and additive number theory.
• He combines sheer technical power, an other-worldly ingenuity for hitting upon new ideas, and a startlingly natural point of view that leaves other mathematicians wondering, " Why didn't anyone see that before?" At 31 years of age, Tao has written over eighty research papers, with over thirty collaborators, and his interests range over a wide swath of mathematics, including harmonic analysis, nonlinear partial differential equations, and combinatorics.
• Another area in which Tao has worked is solving special cases of the equations of general relativity describing gravity.
• Imposing cylindrical symmetry on the equations leads to the "wave maps" problem where, although it has yet to be solved, Tao's contributions have led to a great resurgence of interest since his ideas seem to have made a solution possible.
• Another area where Tao has introduced novel ideas, giving the subject a whole new look, is the theory of the nonlinear Schrodinger equations.
• These equations have considerable practical applications and again Tao's insights have shed considerable light on the behaviour of a particular Schrodinger equation.
• Also in 2006, Tao published Nonlinear dispersive equations.
• This monograph is a remarkable introduction to nonlinear dispersive evolution equations, in particular to their local and global well-posedness and scattering theory.
• Tao's mathematical knowledge has an extraordinary combination of breadth and depth: he can write confidently and authoritatively on topics as diverse as partial differential equations, analytic number theory, the geometry of 3-manifolds, nonstandard analysis, group theory, model theory, quantum mechanics, probability, ergodic theory, combinatorics, harmonic analysis, image processing, functional analysis, and many others.

116. Francesco Cecioni (1884-1968)
• With regard to the more general linear equations with a matrix unknown, the author recalls the works of James Joseph Sylvester.
• In these works, a method according to which it is possible to rationally determine the solution of any linear equation in an unknown matrix, in the case where this equation has only one solution, is described.
• In the first and second chapters of his work, Cecioni discusses some particular linear equations between matrices, but he does this more generally by discussing the conditions of solubility and all of the possible solutions.
• In the first chapter he also touches upon those equations in which the unknown matrix is multiplied by the known matrix always on one side; moreover, he determines, as an example, the conditions of solubility of axb = c.
• In the second chapter he considers, among other things the particularly remarkable equation ax = xb.
• Lastly, in the third chapter he talks about the simplest equation of higher degree, that is xm = a, and tackles the problem of determining the mth root of a matrix and then that of a linear substitution.

117. Luigi Fantappiè (1901-1956)
• As an application the Cauchy theory of partial differential equations is considered.
• A similar discussion of the notions of hyperbolic, parabolic and elliptic partial differential equations which pertain to the case of two independent variables also appears.
• Suddenly I saw the possibility of interpreting a wide range of solutions (the anticipated potentials) of the wave equation which can be considered the fundamental law of the Universe.
• For example in Deduzione autonoma dell'equazione generalizzata di Schrodinger, nella teoria di relativita finale Ⓣ (1955) Fantappie deduces the Klein-Gordan equation in quantum mechanics as a limit, as the radius of the universe tends to infinity, of a classical (non-quantized) equation in his extension of relativity based on a simple (pseudo-orthogonal) group having the Lorentz group as a type of limit.
• Finally let us look briefly at some of the papers which Fantappie published in the last seven years of his life: Costruzione effettiva di prodotti funzionali relativisticamente invarianti Ⓣ (1949) constructs functional scalar products of two functions, as required in quantum mechanics, which are relativistically invariant; Caratterizzazione analitica delle grandezze della meccanica quantica Ⓣ (1952) gives conditions on an hermitian operator that he claims are necessary and sufficient for it to satisfy to represent a physically real observable; Determinazione di tutte le grandezze fisiche possibili in un universo quantico Ⓣ (1952) discusses aspects of group invariance of wave equations; Gli operatori funzionali vettoriali e tensoriali, covarianti rispetto a un gruppo qualunque Ⓣ (1953) discusses the role of operators and Lie groups in a quantum-mechanical universe; Deduzione della legge di gravitazione di Newton dalle proprieta del gruppo di Galilei Ⓣ (1955) shows that the inverse square law is a necessary consequence if certain specific assumptions are made; Les nouvelles methodes d'integration, en termes finis, des equations aux derivees partielles Ⓣ (1955) applies analytic functionals to find explicit solutions of partial differential equations; and Sur les methodes nouvelles d'integration des equations aux derivees partielles au moyen des fonctionnelles analytiques Ⓣ (1956) gives a new method for the solution of Cauchy's problem.

118. James Murray (1931-)
• He also took two special topic papers, namely fluid mechanics and partial differential equations.
• Fundamental equations and wave propagation (1965) and On the mathematics of fluidization.
• After writing a few papers on it I found it quite interesting even though there was nothing too difficult about the mathematics as it was just singular perturbation analysis of the diffusion equation.
• This lead to a wave travelling up the rod, but the wave equation was nonlinear and so a shock developed.
• For example A theoretical study of the effect of impulse on the human torso (1966), A simple method for obtaining approximate solutions for a class of diffusion-kinetic enzyme problems (Part I, 1968; Part II, 1968), and On the molecular mechanism of facilitated oxygen diffusion by haemoglobin and myoglobin (1971) are on mathematical biology while A simple method for determining asymptotic forms of Navier-Stokes solutions for a class of large Reynolds number flows (1967), Singular perturbations of a class of nonlinear hyperbolic and parabolic equations (1968) and On Burgers' model equations for turbulence (1973) are on fluid dynamics.
• Murray has published three single authored books Asymptotic Analysis (1974), Lectures on Nonlinear Differential Equation Models in Biology (1977), Mathematical biology (1989), and, in addition, one multi-author work The mathematics of marriage: dynamic nonlinear models (2002), with John M Gottman, Catherine C Swanson, Rebecca Tyson and Kristin R Swanson.

119. Niels Norlund (1885-1981)
• The thesis is the beginning of the penetrating study of difference equations that he accomplished in the following 15 years.
• The problem in difference equations is to find general methods for determining a function when the size of its increase on intervals of a given length is known.
• a long series of papers developing the theory of difference equations.
• There he gave the lecture Sur les equations aux differences finies Ⓣ.
• This is the first book to develop the theory of the difference calculus from the function-theoretic point of view and to include a significant part of the recent researches having to do with the analytic and asymptotic character of the solutions of linear difference equations.
• This is The logarithmic solutions of the hypergeometric equation (1963) which was reviewed by L J Slater:- .
• In this important paper the author discusses in a clear and detailed way the complete logarithmic solutions of the hypergeometric differential equation satisfied by the Gauss function ..
• Tables are also given for the continuation formulae which hold between the logarithmic and other cases of Riemann's P-function, and the paper concludes with a very clear statement of the logarithmic solutions of the confluent hypergeometric equation satisfied by Kummer's function ..

120. Girolamo Cardano (1501-1576)
• There followed a period of intense mathematical study by Cardan who worked on solving cubic and quartic equations by radical over the next six years.
• I have certainly grasped this rule, but when the cube of one-third of the coefficient of the unknown is greater in value than the square of one-half of the number, then, it appears, I cannot make it fit into the equation.
• In 1540 Cardan resigned his mathematics post at the Piatti Foundation, the vacancy being filled by Cardan's assistant Ferrari who had brilliantly solved quartic equations by radicals.
• In it he gave the methods of solution of the cubic and quartic equation.
• In fact he had discovered in 1543 that Tartaglia was not the first to solve the cubic equation by radicals and therefore felt that he could publish despite his oath.
• Solving a particular cubic equation, he writes:- .
• History Topics: Quadratic, cubic and quartic equations .

121. Francesco Brioschi (1824-1897)
• Francesco Brioschi was an important mathematician in the European context owing to his contributions to the theory of algebraic equations and to the applications of mathematics to hydraulics.
• One of his most important results was his application of elliptical modular functions to the solution of equations of the fifth degree in 1858.
• Brioschi however later went on to solve sixth degree equations using similar techniques.
• In 1888, Maschke proved that a particular sixth-degree equation could be solved by using hyperelliptic functions and Brioschi then showed that any sixth-degree algebraic equation could be reduced to Maschke's equation and therefore solved using hyperelliptic functions.
• In mechanics Brioschi dealt with problems of statics, proving Mobius's results by analytic means; with the integration of equations in dynamics, according to Jacobi's method; with hydrostatics; and with hydrodynamics.

• For example, if the problem reduced to the solution of a quadratic equation, then Yang would solve it numerically, then show how to solve a general quadratic equation numerically.
• What Yang's method essentially reduces to is finding the determinant of the matrix of coefficients of the system of equations.
• The topics covered by Yang include multiplication, division, root-extraction, quadratic and simultaneous equations, series, computations of areas of a rectangle, a trapezium, a circle, and other figures.
• Then a modern solution would set up equations .
• He is subtracting the second equation from the first: 300 - 100 coins, 21 - 1 Wenzhou oranges, 9 - 1 green oranges.
• This is exactly what he is doing! Replace y in the above equation so that .

123. Edmund Whittaker (1873-1956)
• It also develops the theory of special functions and their related differential equations.
• He studied these special functions as arising from the solution of differential equations derived from the hypergeometric equation.
• His results in partial differential equations (described as 'most sensational' by Watson) included a general solution of the Laplace equation in three dimensions in a particular form and the solution of the wave equation.
• He also worked on electromagnetic theory giving a general solution of Maxwell's equation, and it was through this topic that his interest in relativity arose.

124. Joseph Pérès (1890-1962)
• All the equations studied above belong to the general class of equations which can be formed from unknown functions and known functions by additions and compositions.
• We have developed two principal methods for solving them: the first consists in reducing them to a solvable equation by successive approximations, the reduction being entirely realized (Chapter I, equations of paragraphs I and II), or obtaining by derivation [Volterra equation of the first kind, equation (e) of Chapter III] and by change of unknown (Chapter II).
• Peres' work on analysis and mechanics was always influenced by Volterra, extending results of Volterra's on integral equations.

125. H T H Piaggio (1884-1967)
• His most famous work, An Elementary Treatise on Differential Equations, was published by G Bell & Sons in 1920.
• Here list a few articles which Piaggio published in The Mathematical Gazette: Relativity rhymes with a mathematical commentary (January 1922); Geometry and relativity (July 1922); Mathematics for evening technical students (July 1924); Mathematical physics in university and school (October 1924); Probability and its applications (July 1931); Three Sadleirian professors: A R Forsyth, E W Hobson and G H Hardy (October 1931); Mathematics and psychology (February 1933); Lagrange's equation (May 1935); Fallacies concerning averages (December 1937); and The incompleteness of "complete" primitives of differential equations (February 1939).
• In the Proceedings of the Glasgow Mathematical Association he published Exceptional integrals of a not completely integrable total differential equation (1953).
• The usual theory of a single Pfaffian equation holds if the coefficients are of class C'.
• He read papers to the Society such as Note on Linear Differential Equations with constant coefficients on 10 May 1912.
• H T H Piaggio's Treatise on Differential Equations .

126. Joseph Keller (1923-2016)
• First an inhomogeneous integral equation is derived for the sound field in an infinite medium containing a thin curved shell of different material.
• By appropriate approximations, the solution of the integral equation is reduced to the evaluation of a surface integral.
• Keller's first two single-author papers appeared in 1948: On the solution of the Boltzmann equation for rarefied gases; and The solitary wave and periodic waves in shallow water.
• In particular, they present the definition of the integral given by E Nelson (1964), and show that the integral does satisfy the corresponding appropriate Schrodinger equation.
• It also served as a starting point for development of the modern theory of linear partial differential equations .
• Other areas in which he has contributed include singular perturbation theory, bifurcation studies in partial differential equations, nonlinear geometrical optics and acoustics, inverse scattering, effective equations for composite media, biophysics, biomechanics, carcinogenesis, optimal design, hydrodynamic surface waves, transport theory, and waves in random media.

127. William Whyburn (1901-1972)
• His thesis advisor was Hyman Joseph Ettlinger (1889-1986), who had been a student of G D Birkhoff, and Whyman was awarded a doctorate in June 1927 for his thesis Linear Boundary Value Problems for Ordinary Differential Equations and Their Associated Difference Equations.
• However, Whyburn had already published three papers before submitting his doctoral thesis, namely An extension of the definition of the Green's function in one dimension (1924), On the Green's function for systems of differential equations (1927) and On the polynomial convergents of power series (1927).
• This definition applies to linear differential systems of the nth order where the coefficients of the differential equation are continuous functions and the coefficients of the n linearly independent boundary conditions are constants.
• This extended definition of the Green's function is used to carry over the results that have been obtained for these differential systems to integral equations whose kernels are in general analytic functions of a parameter.
• On the contrary, he wrote around 40 papers on differential equations.
• Monthly 57 (2) (1950), 124-126.','1] under the areas: Boundary value problems; Systems of difference equations; General existence theorems, and functional properties of solutions; Specific properties of Green's functions and Green's matrices; and Nonlinear matrix differential equations.
• Closely related to this work on differential equations is his papers on the theory of the Lebesgue integral following Frigyes Riesz's approach of approximation by step functions.

128. Francesco Tricomi (1897-1978)
• In this paper he studied the theory of partial differential equations of mixed type, in particular the equation .
• now known as the 'Tricomi equation'.
• The equation became important in describing an object moving at supersonic speed.
• Of course there were no supersonic aircraft in 1923 but the equation was to play a major role in later studies of supersonic flight.
• These papers cover a vast range of subjects including singular integrals, differential and integral equations, pseudodifferential operators, functional transforms, special functions, probability theory and its applications to number theory.
• As well as having the 'Tricomi equation' named after him, there are also special functions called 'Tricomi functions'.

129. Édouard Goursat (1858-1936)
• He began teaching at the University of Paris in 1879, receiving his doctorate in 1881 from l'Ecole Normale Superieure for his thesis Sur l'equation differentialle lineaire qui admet pour integrale la serie hypergeometrique Ⓣ.
• Goursat's papers on the theory of linear differential equations and their rational transformations, as well as his studies on hypergeometric series, Kummer's equation, and the reduction of abelian integrals form, in the words of Picard "a remarkable ensemble of works evolving naturally one from the other".
• Goursat introduced the notion of orthogonal kernels and semiorthogonals in connection with Erik Fredholm's work on integral equations.
• In 1891 Goursat wrote Lecons sur l'integration des equations aux derivees partielles du premier ordre Ⓣ.
• Volume 2 explores functions of a complex variable and differential equations.
• Volume 3 surveys variations of solutions and partial differential equations of the second order and integral equations and calculus of variations.

130. Ivan Vidav (1918-2015)
• They often discussed mathematics of all kinds and on one occasion, after his lecture in 1940, Plemelj mentioned to Vidav an open problem concerning homogeneous linear differential equations.
• His work identifies and explains fully the various problems in the theory of linear differential equations, problems that intrigued many mathematicians but none was able to penetrate to their core.
• This first original scientific work of Vidav, in which he considered the so-called Fuchsian differential equation with five singular points, became the basis of his dissertation entitled The theorems of Klein in the theory of linear differential equations.
• At first he continued working on problems in differential equations.
• For instance, he participated at the 11th International Congress of Mathematicians at Harvard University in Cambridge, USA, from 30 August to 6 September in 1950, where he gave a short report on his own results on Fuchsian equations with five or six singularities.
• He published several results on strongly continuous semigroups of operators, connected with the linear Boltzmann equation (mostly in Journal of Mathematical Analysis and Applications), sometimes in cooperation with other mathematicians and physicists.

131. Friedrich Engel (1861-1941)
• With my investigations of differential equations which permit a finite continuous group, I've always had a vague idea of the analogy between substitution theory and transformation theory.
• One can prove that certain problems in integration can be reduced to certain ancillary equations of particular order and with particular characteristics, while further reduction is impossible in general.
• How far the analogy with the algebraic equations can be carried through, I can't say for the good reason that I have almost no knowledge of equation theory.
• Lie had, for some time, thought of writing a larger work on transformation groups, but, without the impetus from the outside which he now was getting, it would have quite surely gone the way of the work on first-order partial differential equations which he had made plans to do in the eighteen-seventies.
• His first course of lectures was 'Theory of first-order partial differential equations' which he gave in the winter semester of 1885-86.
• He also wrote on continuous groups and partial differential equations, translated works of Lobachevsky from Russian to German, wrote on discrete groups, Pfaffian equations and other topics.
• If Lie had lived for a longer time and had summarised his ideas on partial differential equations of the first order in the form of a textbook, the book would be about the same as these lectures of his collaborator.

132. Germund Dahlquist (1925-2005)
• BESK came into operation in December 1953 and Dahlquist used the machine to solve differential equations.
• During this time Dahlquist wrote a number of papers such as The Monte Carlo-method (1954), Convergence and stability for a hyperbolic difference equation with analytic initial-values (1954), and Convergence and stability in the numerical integration of ordinary differential equations (1956).
• He submitted his doctoral thesis Stability and error bounds in the numerical integration of ordinary differential equations to Stockholm University in 1958, defending it in a viva in December.
• Dahlquist was to use this idea throughout his research in stiff differential equations.
• In the same year of 1963 he published Stability questions for some numerical methods for ordinary differential equations, an expository paper on his fundamental results concerning stability of difference approximations for ordinary differential equations.
• Awarded to a young scientist (normally under 45) for original contributions to fields associated with Germund Dahlquist, especially the numerical solution of differential equations and numerical methods for scientific computing.
• He has created the fundamental concepts of stability, A-stability and the nonlinear G-stability for the numerical solution of ordinary differential equations.

133. Ilya Vekua (1907-1977)
• In particular, the work of Ilya Vekua in the field of so-called 'singular integral equations' had a great influence on the direction of my own work, and I felt it my pleasant duty to emphasize that fact in the introduction to my monograph in this area.
• Advised by Aleksei Krylov, Niko Muskhelishvili and Vladimir Smirnov, Vekua undertook research on the equations of mathematical physics at the USSR Academy of Sciences in Leningrad for his Candidate's Degree (equivalent to a Ph.D.) [',' N N Bogoljubov, M A Lavrent’ev and A V Bicadze, Ilja Nestorovic Vekua (on the occasion of his seventieth birthday) (Russian), Complex analysis and its applications (Russian) 664 (’Nauka’, Moscow, 1978), 3-21.','7]:- .
• or habilitation) "A complex representation of solutions of elliptic differential equations and its application to boundary value problems".
• In the following year he became a professor in the Department of Differential Equations of Lomonosov State University of Moscow.
• In the early 1930s Carleman and Theoclorescu showed that a number of properties of analytic functions of one complex variable could be transferred to the solution of an elliptic system of two first order differential equations in the case of two real independent variables.
• There is New Methods for Solving Elliptic Equations (Russian) (1948) and, a book mentioned above, Generalized analytic functions (Russian) (1959).
• By generalized analytic functions are meant functions of two real variables which obey elliptic differential equations analogous to the Cauchy-Riemann equations.
• As to Vekua's personality, we quote from his friend Lipman Bers [',' A V Bitsadze, The life and scientific activity of I N Vekua (Russian), Partial differential equations and their applications (Russian), Tbilisi, 1982 (Tbilis.

134. John F Nash (1928-2015)
• Meanwhile he went to Levinson to inquire about a differential equation that intervened and Levinson says it is a system of partial differential equations and if he could only [get] to the essentially simpler analog of a single ordinary differential equation it would be a damned good paper - and Nash had only the vaguest notions about the whole thing.
• His research on the theory of real algebraic varieties, Riemannian geometry, parabolic and elliptic equations was, however, extremely deep and significant in the development of all these topics.
• After this Nash worked on ideas that would appear in his paper Continuity of solutions of parabolic and elliptic equations which was published in the American Journal of Mathematics in 1958.
• The outstanding results which Nash had obtained in the course of a few years put him into contention for a 1958 Fields Medal but since his work on parabolic and elliptic equations was still unpublished when the Committee made their decisions he did not make it.
• striking and seminal contributions to the theory of nonlinear partial differential equations and its applications to geometric analysis.

135. Myron Mathisson (1897-1940)
• Mathisson studied general dynamical laws governing the motion of a particle, with possibly a spin or an angular momentum, in a gravitational or electromagnetic field, and developed a powerful method for passing from field equations to particle equations.
• Mathisson proved that the variational equation can be solved when it has been defined so that the equations to be imposed upon the characteristic tensor will be compatible with the variations allowed in the fields.
• He obtained the equations of motion for the angular momentum and for the centre of mass with arbitrary external forces.
• Finally, he calculated the linear forces for the case of no electric moment, leading to the equations for linear motion.
• M Mathisson, The variational equation of relativistic dynamics, Proc.

136. Anton Dimitrija Bilimovic (1879-1970)
• He graduated with the gold medal in 1903 and was awarded a Master's degree (equivalent to a doctorate) in 1903 from Kiev University for his thesis Equations of motion for conservative systems and its application.
• At this time Hilbert was undertaking research into integral equations, work which led him to develop functional analysis.
• At the end of this analysis, using the energy integral, he eliminated time in the differential equations of motion.
• Especially in rational mechanics, he was occupied by phenomenological principles, motion of the rigid body around fixed point, dynamics of elastic bodies and equations of motion.
• Sur le mouvement d'un corps solide avec un corps supplementaire mobile Ⓣ (1939) examines the differential equations governing the motion of a system consisting of two rigid bodies A and B subject to the constraint that the relative motion of B is specified as a function of the motion of A.
• A natural property of the differential equation of a conic section (Serbian) (1946) discusses some classical metric, intrinsic and projective relations for a conic section.
• Pfaff's method in the geometrical optics (Serbian) (1946) derives the Hamiltonian equations in optics from Fermat's principle using vector notation.
• Pfaff's expression and Pfaff's equations are closely related to other mathematical concepts, which occupy an important place in modern mathematics.
• The relation between Pfaff's expression and differential equations in canonical form was established by George Prange and Ernst Schering.

137. Marion Gray (1902-1979)
• in 1926 for her thesis The theory of singular ordinary differential equations of the second order having offered physics as an allied subject.
• In 1925 E T Whittaker communicated the paper The equation of conduction of heat by Marion C Gray to the Royal Society of Edinburgh.
• Marion C Gray and S A Schelkunoff, The approximate solution of linear differential equations.
• Various papers by Gray were read to the Society: The equation of telegraphy (which appeared in volume 42 of the Proceedings and she read to the meeting of the Society in November 1923), The equation of conduction of heat (which also appeared in volume 42 of the Proceedings), and On the equation of heat (which appeared as Particular solutions of the equation of conduction of heat in one dimension in volume 43 of the Proceedings).

138. Ivo Babuska (1926-)
• His first papers, all written in Czech, were Welding stresses and deformations (1952), Plane elasticity problem (1952), A contribution to the theoretical solution of welding stresses and some experimental results (1953), A contribution to one method of solution of the biharmonic problem (1954), Solution of the elastic problem of a half-plane loaded by a sequence of singular forces (1954), (with L Mejzlik) The stresses in a gravity dam on a soft bottom (1954), On plane biharmonic problems in regions with corners (1955), (with L Mejzlik) The method of finite differences for solving of problems of partial differential equations (1955), and Numerical solution of complete regular systems of linear algebraic equations and some applications in the theory of frameworks (1955).
• Basically, the mathematical problem Babuska's group had to solve was to find a numerical solution to a nonlinear partial differential equation.
• From the mathematical point of view it deals with the special method of solving a biharmonic equation for given boundary conditions.
• His next important book, published in collaboration with Milan Prager and Emil Vitasek in 1964, was Numerical Solution of Differential Equations (Czech).
• It was translated into English and published under the title Numerical processes in differential equations two years later.
• Among the many other services to mathematics which Babuska has given, we mention the many journals which have benefited by his accepting a position on their editorial board: Communications in Applied Analysis; Communications in Numerical Methods in Engineering; Computer & Mathematics; Computer Methods in Applied Mechanics and Engineering; Computers and Structures; Communications in Applied Analysis; International Journal for Numerical Methods in Engineering; Modelling and Scientific Computing; Numerical Mathematics - A Journal of Chinese Universities; Numerical Methods for Partial Differential Equations; and Siberian Journal of Computer Mathematics.

139. Pierre-Simon Laplace (1749-1827)
• His next paper for the Academy followed soon afterwards, and on 18 July 1770 he read a paper on difference equations.
• This paper contained equations which Laplace stated were important in mechanics and physical astronomy.
• Not only had he made major contributions to difference equations and differential equations but he had examined applications to mathematical astronomy and to the theory of probability, two major topics which he would work on throughout his life.
• The main mathematical approach here is the setting up of differential equations and solving them to describe the resulting motions.
• In the Mecanique Celeste Ⓣ Laplace's equation appears but although we now name this equation after Laplace, it was in fact known before the time of Laplace.

140. Brook Taylor (1685-1731)
• He gave an account of an experiment to discover the law of magnetic attraction (1715) and an improved method for approximating the roots of an equation by giving a new method for computing logarithms (1717).
• It was, wrote Taylor, due to a comment that Machin made in Child's Coffeehouse when he had commented on using "Sir Isaac Newton's series" to solve Kepler's problem, and also using "Dr Halley's method of extracting roots" of polynomial equations.
• Taylor initially derived the version which occurs as Proposition 11 as a generalisation of Halley's method of approximating roots of the Kepler equation, but soon discovered that it was a consequence of the Bernoulli series.
• The second version occurs as Corollary 2 to Proposition 7 and was thought of as a method of expanding solutions of fluxional equations in infinite series.
• These include singular solutions to differential equations, a change of variables formula, and a way of relating the derivative of a function to the derivative of the inverse function.
• Taylor, in his studies of vibrating strings was not attempting to establish equations of motion, but was considering the oscillation of a flexible string in terms of the isochrony of the pendulum.
• He tried to find the shape of the vibrating string and the length of the isochronous pendulum rather than to find its equations of motion.

141. Sijue Wu (1964-)
• However, the full equations governing the motion of the waves are notoriously difficult to work with because of the free boundary and the inherent nonlinearity, which are non-standard and non-local.
• Although many approximate treatments, such as linear theory and shallow-water theory as well as numerical computations, have been used to explain many important phenomena, it is certainly of importance to study the solutions of the equations which include the effects neglected by approximate models.
• Her research interests centre on harmonic analysis and partial differential equations, in particular nonlinear equations from fluid mechanics.
• The Ruth Lyttle Satter Prize in Mathematics is awarded to Sijue Wu for her work on a long-standing problem in the water wave equation, in particular for the results in her papers (1) "Well-posedness in Sovolev spaces of the full water wave problem in 2-D" (1997); and (2) "Well-posedness in Sobolev spaces of the full water wave problem in 3-D" (1999).
• By applying tools from harmonic analysis (singular integrals and Clifford algebra), she proves that the Taylor sign condition always holds and that there exists a unique solution to the water wave equations for a finite time interval when the initial wave profile is a Jordan surface.
• Recently, Wu's research has focused on nonlinear equations from fluid dynamics.
• The Birkhoff-Rott equations provide a mathematical description of the evolution of a vortex sheet.
• It is a longstanding open problem to determine a function space in which these equations are well-posed, or, alternatively, to describe the evolution past singularity formation; this is the problem addressed in the present paper.

142. Josif Zakharovich Shtokalo (1897-1987)
• His research on the theory of functions of a complex variable and its applications included work on conformal mappings, differential equations, and variational statistics.
• However, during the second half of the 1930s he worked almost exclusively on differential equations.
• Shtokalo continued to undertake research on differential equations while in Ufa, but the direction of his research was at this time influenced by the joint work of Bogolyubov with Nikolai Mitrofanovich Krylov in which they developed a theory of non-linear oscillations; they called their topic 'non-linear mechanics'.
• or the habilitation) on Asymptotic and Symbolic-Analytic Methods in the Solution of Certain Classes of Linear Differential Equations with Variable Coefficients.
• In 1945 several papers appeared including: Methode asymptotique pour la solution de certaines classes d'equations differentielles lineaires a coefficients variables Ⓣ; Generalisation de la formule fondamentale de la methode symbolique pour le cas des equations differentielles a coefficients variables Ⓣ; Criteria for stability and instability of the solutions of linear differential equations with quasiperiodic coefficients (Ukrainian, Russian), Linear differential equations of the n th order with quasiperiodic coefficients (Ukrainian, Russian), Systems of linear differential equations with quasiperiodic coefficients (Ukrainian, Russian), and Generalized Gibbs formula for the case of linear differential equations with variable coefficients (Ukrainian, Russian).
• Shtokalo worked mainly in the areas of differential equations, operational calculus and the history of mathematics.
• After 1945 he became particularly interested in the qualitative and stability theory of solutions of systems of linear ordinary differential equations in the Lyapunov sense and in the 1940s and 1950 published a series of articles and three monographs in these areas.
• Shtokalo's work had a particular impact on linear ordinary differential equations with almost periodic and quasi-periodic solutions.
• He extended the applications of the operational method to linear ordinary differential equations with variable coefficients.
• In the following year his 128-page monograph Operational methods and their development in the theory of linear differential equations with variable coefficients (Russian) was published.
• In 1961 the English text Linear differential equations with variable coefficients.
• It differs from other books in this domain by the consideration of solutions of ordinary differential equations with variable coefficients, based on papers of the author and of K G Valeev.
• Teacher in primary, intermediate, and advanced schools, scholar, organiser and director of scientific endeavours, researcher in the area of the theory of differential equations, in the domain of operational calculus, in the area of the history of mathematics, organiser of the publication of works which are classics of indigenous science - such is a far from complete enumeration of the contributions of Iosif Zakharovich Shtokalo to the development of domestic science and culture.

143. Oleksandr Mikolaiovich Sharkovsky (1936-)
• He had already published a number of high quality papers (all in Russian), such as: Necessary and sufficient conditions for convergence of one-dimensional iterative processes (1960), Rapidly converging iterative processes (1961), Solutions of a class of functional equations (1961), and The reducibility of a continuous function of a real variable and the structure of the stationary points of the corresponding iteration process (1961).
• He was made head of the Department of Differential Equations at the Institute of Mathematics at the Ukrainian branch of the USSR Academy of Sciences in 1974.
• He also works in the theory of functional and functional differential equations, and the study of difference equations and their application.
• The book, written with G P Pelyakh, Introduction to the theory of functional equations (Russian) was published in 1974.
• In 1986, in collaboration with Yu L Maistrenko and E Yu Romanenko, Sharkovsky published the Russian monograph Difference equations and their applications.
• The book contains four parts: (I) One-dimensional dynamical systems; (II) Difference equations with continuous time ; (III) Differential-difference equations ; and (IV) Boundary-value problems for hyperbolic systems of partial differential equations.
• The aim of the present book is to acquaint the reader with some recently discovered and (at first sight) unusual properties of solutions to nonlinear difference equations.
• These properties enable us to use difference equations in order to model complicated oscillating processes (this can often be done in those cases when it is difficult to apply ordinary differential equations).
• Difference equations are also a useful tool in synergetics - an emerging science concerned with the study of ordered structures.
• The application of these equations opens up new approaches in solving one of the central problems of modern science - the problem of turbulence.
• This book is especially interesting for specialists in differential equations applying their results to some practical problems in the natural sciences and technology.

144. Leslie Fox (1918-1992)
• We should note that Fox was undertaking numerical work solving partial differential equations which arose in engineering problems but which could not be solved by analytic techniques.
• For example he published Some improvements in the use of relaxation methods for the solution of ordinary and partial differential equations (1947), A short account of relaxation methods (1948), and The solution by relaxation methods of ordinary differential equations (1949).
• This book was The numerical solution of two-point boundary problems in ordinary differential equations and it is a great tribute to his expository skills that it was reprinted by Dover Publications in 1990.
• The book summarises at an elementary level the methods for numerical construction of the solutions of boundary-value problems which can be expressed in terms of ordinary differential equations of orders one to four.
• With a practical yet rigorous approach, methods to investigate topics such as recurrence relations, zeros of polynomials, linear equations, eigenvalues and eigenvectors, approximations, interpolation, integration, and ordinary differential equations are described and analysed.
• Another collaboration between Fox and Mayers led to Numerical solution of ordinary differential equations published in 1987, four years after Fox retired.
• Though there are two main types of ordinary differential equations, those of initial value type and those of boundary value type, most books until quite recently have concentrated on the former, and again until recently the boundary value problem has had little literature.
• Some numerical experiments with eigenvalue problems in ordinary differential equations (1960) considers methods for solving such equations using a computer.
• Partial differential equations (1963) is summarised by Fox as follows:- .
• This expository paper discusses the present state of our ability to solve partial differential equations.
• Outstanding problems include a determination of the error of finite-difference approximations, the automatic machine production of finite-difference formulae in complicated regions, the smoothing of physical data, and the classification of equations for computing-machine library routines.
• Some of his later papers examine numerical methods for factorising polynomials, for solving elliptic partial differential equations, and methods for treating singularities in boundary value problems.

145. Hajer Bahouri (1958-)
• His mathematical area of interest was partial differential equations.
• He was interested in differential geometry, partial differential equations and mathematical physics.
• Her thesis for this degree was Unicite, non unicite et continuite Holder du probleme de Cauchy pour des equations aux derivees partielles: propagation du front d'onde Cρ pour des equations non lineaires ρ for nonlinear equations',6448)">Ⓣ and again she was advised by Serge Alinhac.
• Her paper Quasilinear wave equations and microlocal analysis, written jointly with Jean-Yves Chemin, was published in Volume 3 of the Proceeding of the Congress.
• He was awarded his Doctorat d'etat in 1989 for a thesis on singularities of non-linear hyperbolic partial differential equations.
• In 2003 she was made Director of the newly established Laboratoire Equations aux Derivees Partielles at the University of Tunis.
• Finally let us look at the book Fourier analysis and nonlinear partial differential equations which Bahouri wrote in collaboration with Jean-Yves Chemin and Raphael Danchin.
• We quote from the review of this book written by Peter Massopust [',' P R Massopust, Review: Fourier analysis and nonlinear partial differential equations, by Hajer Bahouri, Jean-Yves Chemin and Raphael Danchin, Mathematical reviews MR2768550n(2011m:35004).','4]:- .
• This book intends to prepare the reader how to apply tools from Fourier analysis to directly solve problems arising in the theory of nonlinear partial differential equations.
• The authors have three goals: First, they present a detailed account of the tools and methods from harmonic analysis that are presently used to solve nonlinear partial differential equations.
• They consider, among others, evolution equations such as transport and heat equations, linear or quasi-linear symmetric hyperbolic systems, linear, semi-linear and quasi-linear wave equations, and linear and semi-linear Schrodinger equations.n..
• The goal set by the authors, namely to present the Fourier-analytic tools in such a way that they can be directly applied to the solution of nonlinear differential equations, is met for all the applications studied.

146. Jürgen Moser (1928-1999)
• The difficulty that Moser had no money was overcome and he began to study the spectral theory of differential equations with Rellich as his advisor.
• In 1955 several of Moser's papers were published including Singular perturbation of eigenvalue problems for linear differential equations of even order, and Nonexistence of integrals for canonical systems of differential equations.
• Moser worked in ordinary differential equations, partial differential equations, spectral theory, celestial mechanics, and stability theory.
• Next is Stable and random motions in dynamical systems (1973, reprinted 2001) which describes how stable behaviour and statistical behaviour take place together in analytic conservative systems of differential equations.
• Here Moser examines inverse spectral theory for the one-dimensional Schrodinger equation with the aim, as he writes in the introduction, of showing that:- .
• For his fundamental work on stability in Hamiltonian mechanics and his profound and influential contributions to nonlinear differential equations.

147. Alexander Ostrowski (1893-1986)
• One consequence of this association was his monograph Solution of equations and systems of equations which was published in 1960 and was the result of a series of lectures he had given at the National Bureau of Standards.
• By 1973 the third edition of this monograph appeared, this time with a new title: Solution of equations in Euclidean and Banach spaces.
• These are determinants, linear algebra, algebraic equations, multivariate algebra, formal algebra, number theory, geometry, topology, convergence, theory of real functions, differential equations, differential transformations, theory of complex functions, conformal mappings, numerical analysis and miscellany.
• His work on algebraic equations involved a study of the fundamental theorem of algebra, Galois theory, and estimating the roots of algebraic equations.
• Other work of Ostrowski was on the Cauchy functional equation, the Fourier integral formula, Cauchy-Frullani integrals, and the Euler-Maclaurin formula.

148. Lothar Collatz (1910-1990)
• Among his early papers are Genaherte Berechnung von Eigenwerten Ⓣ (1939) in which he considers various methods of approximating characteristic values, Das Hornersche Schema bei komplexen Wurzeln algebraischer Gleichungen Ⓣ (1940) in which he presents a more efficient way of using Horner's method to approximate the complex roots of an algebraic equation, and Schrittweise Naherungen bei Integralgleichungen und Eigenwertschranken Ⓣ (1940) in which inequalities between the eigenvalues of certain integral equations are studied.
• Eigenwertprobleme und ihre numerische Behandlung Ⓣ (1945) contains three parts, the first containing a collection of practical applications which lead to boundary value problems for ordinary and partial differential equations.
• This was followed by Numerische Behandlung von Differentialgleichungen Ⓣ (1951) which provides a comprehensive text on numerical methods for solving differential equations.
• This small book gives a wealth of information on differential equations.
• The book Aufgaben aus der Angewandten Mathematik Ⓣ (1972) (with J Albrecht) provides a collection of problems (with their solutions) on the solution of equations and systems of equations, interpolation, quadrature, approximation, and harmonic analysis.
• Later texts by Collatz include Optimization problems (1975) and Differential equations (1986), the second of these being an English translation of an earlier German book.

149. David Enskog (1884-1947)
• Enskog's thesis studied the Maxwell-Boltzmann equations.
• Enskog began to work on this equation for his master's degree at Uppsala and made a remarkable prediction.
• Hilbert published a new approach to the Maxwell-Boltzmann equations in 1912.
• How to extend the Maxwell-Boltzmann equation to include collisions of more than two bodies was not clear.
• Chapman, who was still working on the Maxwell-Boltzmann equations, immediately saw the importance of Enskog's methods and developed them further.
• In 1917 Enskog published his Uppsala Dissertation, in which he perfected the determination of f from Boltzmann's equation.

150. Demetrios Magiros (1912-1982)
• This part includes papers on nonlinear differential equations, mathematical modelling of physical phenomena and linearization of nonlinear models.
• Linearization by exact methods which presents various "exact" methods of linearizing problems in differential equations; On the linearization of nonlinear models of phenomena.
• Linearization by approximate methods in which he points out that "approximate" linearizations may lose the whole qualitative behaviour of the original nonlinear equation; and Characteristic properties of linear and nonlinear systems in which he gives many examples, recalls the importance of identifying characteristic properties of solutions, such as the superposition property for linear systems, and the possibility of limit cycles and self-excited oscillations in nonlinear systems.
• Two papers which Magiros published in 1977 are: Nonlinear differential equations with several general solutions in which he gives specific devices for finding solutions of some nonlinear ordinary differential equations; and The general solutions of nonlinear differential equations as functions of their arbitrary constants presenting some nonlinear differential equations for which, surprisingly, some superposition does occur, that is, there are families of solutions depending linearly on arbitrary constants.
• covers a variety of topics from special functions and transforms to numerical methods for the solution of nonlinear differential equations and optimal control problems.

151. Mineo Chini (1866-1933)
• In another short note the author indicates a procedure by which he obtains sequences of differential polynomials appearing in the theory of partial differential equations of the second order, with equal invariants, which have already been considered by Darboux.
• In the last of his memoirs, the author studies what conditions a partial differential equation of the 2nd order must satisfy so that, with convenient change of variable, it can be reduced to contain only the second mixed derivative, and one of the first derivatives.
• He developed an interest in both scientific research and in pedagogy: he wrote around forty scientific papers mostly focusing on differential geometry and differential equations and also wrote various books on the problems related to teaching in secondary schools and high schools, which received noteworthy praise for their simplicity and clarity.
• In the first part, entitled Complements of Algebra, the following topics are presented: Progressions, Logarithms, Combinatorial Analysis, Binomials, Determinants, and Systems of Linear Equations.
• With clarity, Chini was able to successfully present the concepts of sequences, logarithms, combinatorics, determinants, systems of linear equations and their resolution, elements of analytic geometry and of differential and integral calculus while trying to give an idea, through examples taken from physics and chemistry, of how the theory, still under development, could be well utilised outside the abstract field of mathematics.
• Chini treated, in a clear and ordered way, differential equations of the first and second order, integration by series of differential equations and partial derivatives of the first and second order.
• Again, he was identifying the deficiencies of the course in the modest weekly timetable, in the lack of parallel courses of mathematics and in the very abstract study of integration of differential equations.

152. Lewis Fry Richardson (1881-1953)
• He first developed his method of finite differences in order to solve differential equations which arose in his work for the National Peat Industries concerning the flow of water in peat.
• a scheme of weather prediction which resembles the process by which the Nautical Almanac is produced in so far as it is founded upon the differential equations and not upon the partial recurrence of phenomena in their ensemble.
• Making observations from weather stations would provide data which defined the initial conditions, then the equations could be solved with these initial conditions and a prediction of the weather could be made.
• It was a remarkable piece of work but in a sense it was ahead of its time since the time taken for the necessary hand calculations in a pre-computer age took so long that, even with many people working to solve the equations, the solution would be found far too late to be useful to predict the weather.
• However the way that Richardson modelled the causes of war was quite different, giving systems of differential equations which governed the interactions between countries caused by such things as attitudes and moods.
• The equations are merely a description of what people would do if they did not stop and think.
• He set up equations governing arms build-up by nations, taking into account factors such as the expense of an arms race, grievances between states, ambitions of states, etc.
• Choosing different values for the various parameters in the equation he then tried to investigate when situations were stable and when they were unstable.

153. Hans Meinhardt (1938-2016)
• However, recently it was shown that basic types of the molecular interaction allowing pattern formation can be described by sets of coupled partial differential equations.
• Kinetic theory has dealt mainly with the interplay of an autocatalytic and slowly diffusing activator with a rapidly diffusing inhibitor, which was hypothesised over 30 years ago by Turing to be "the chemical basis of morphogenesis." More recent elaborations, retaining this concept, have replaced Turing's linear equations with more complex nonlinear ones.
• Many biologists are presumably afraid of any mathematics and stop reading a paper after the first equation is encountered.
• Thus, equations are better put 'in quarantine', into an appendix or into supplementary material if the paper should appear in an experimentally oriented journal.
• This is a pity since an equation unambiguously shows within a few lines what the hypothesis really is.
• Thus, educating students so that they can later approach and appreciate an equation without fear would be most helpful.

154. Émile Mathieu (1835-1890)
• For this degree he presented his paper Nouveaux theoremes sur les equations algebriques Ⓣ which was examined by Jean-Marie Duhamel.
• Mathieu chose as topics for his course the methods of integration in mathematical physics, the theory of numbers and the algebraic resolution of the equations.
• From his late twenties his main efforts were devoted to the then unfashionable continuation of the great French tradition of mathematical physics, and he extended in sophistication the formation and solution of partial differential equation for a wide range of physical problems.
• He discovered these functions, which are special cases of hypergeometric functions, while solving the wave equation for an elliptical membrane moving through a fluid.
• The Mathieu functions are solutions of the Mathieu equation which is .
• In his 'Theory of capillarity' he lays aside the direct consideration of the capillary forces employed by Poisson, and follows Gauss in establishing the equations for the various problems by seeking to determine the minimum of the potential of the active forces.
• In the 'Theory of the elasticity of solid bodies' he invariably uses the principle of virtual velocities to throw the problems of equilibrium into equations.

155. Nikolai Mitrofanovich Krylov (1879-1955)
• He worked mainly on interpolation and numerical solutions to differential equations, where he obtained very effective formulas for the errors.
• For example he published On the approximate solution of the integro-differential equations of mathematical physics (1926), and Approximation of periodic solutions of differential equations in French in 1929.
• With his collaborator and former student N N Bogolyubov, he published On Rayleigh's principle in the theory of differential equations of mathematical physics and on Euler's method in calculus of variations (1927-8) and On the quasiperiodic solutions of the equations of the nonlinear mechanics.
• Examples of physical systems are given which lead to the type of equation considered in the monograph.
• Moreover, general statements of methods for solving equations are illustrated by the explicit solution of examples.
• We present the fundamental results of the works of N M Krylov and N N Bogolyubov devoted to the establishment of effective error estimates for the Ritz method, the Bubnov-Galerkin method and the least squares method in connection with self-adjoint differential equations.
• In 1939 Krylov and Bogolyubov published Sur les equations de Focker-Planck deduites dans la theorie des perturbations a l'aide d'une methode basee sur les proprietes spectrales de l'hamiltonien perturbateur (Application a la mecanique classique et a la mecanique quantique).

156. Charles-François Sturm (1803-1855)
• One of Sturm's most famous papers Memoire sur la resolution des equations numeriques Ⓣ was published in 1829.
• It considered the problem of determining the number of real roots of an equation on a given interval.
• The 1829 paper was not the last of Sturm's work on this algebraic equations and in [',' H Sinaceur, Cauchy, Sturm et les racines des equations, in Etudes sur Cauchy (1789-1857), Rev.
• seeks to determine the mutual influence between A-L Cauchy's and Ch-F Sturm's research from 1829 to around 1840 on the roots of algebraic equations.
• These were the years during which he published some important results on differential equations.
• Sturm became interested in obtaining results on specific differential equations which occurred in Poisson's theory of heat.
• Liouville was also working on differential equations derived from the theory of heat.
• Papers of 1836-1837 by Sturm and Liouville on differential equations involved expansions of functions in series and is today well-known as the Sturm-Liouville problem, an eigenvalue problem in second order differential equations.

157. Hidehiko Yamabe (1923-1960)
• This was a period when his mathematical interests began to move away from Lie groups to differential equations and differential geometry.
• His next major research contribution was Kernel functions of diffusion equations.
• This paper presents a new, elegant method for constructing Green's function G for the heat equation over any domain D in Euclidean space.
• In the following year Yamabe published A unique continuation theorem for solutions of a parabolic differential equation written jointly with Seizo Ito.
• The same theme was taken up in A unique continuation theorem of a diffusion equation which he published in 1959.
• His second paper on Kernel functions of diffusion equations was published in 1959 and in the following year he published On a deformation of Riemannian structures on compact manifolds and Global stability criteria for differential systems.

158. Charles Hermite (1822-1901)
• Also like Galois he was attracted by the problem of solving algebraic equations and one of the two papers attempted to show that the quintic cannot be solved in radicals.
• The letters he exchanged with Jacobi show that Hermite had discovered some differential equations satisfied by theta-functions and he was using Fourier series to study them.
• He had found general solutions to the equations in terms of theta-functions.
• Although an algebraic equation of the fifth degree cannot be solved in radicals, a result which was proved by Ruffini and Abel, Hermite showed in 1858 that an algebraic equation of the fifth degree could be solved using elliptic functions.
• Hermite is now best known for a number of mathematical entities that bear his name: Hermite polynomials, Hermite's differential equation, Hermite's formula of interpolation and Hermitian matrices.

159. Sun-Yung Alice Chang (1948-)
• Chang's research interests include the study of certain geometric types of nonlinear partial differential equations.
• The Ruth Lyttle Satter Prize is awarded to Sun-Yung Alice Chang for her deep contributions to the study of partial differential equations on Riemannian manifolds and in particular for her work on extremal problems in spectral geometry and the compactness of isospectral metrics within a fixed conformal class on a compact 3-manifold.
• Yang and I have solved the partial differential equation of Gaussian/scalar curvatures on the sphere by studying the extremal functions for certain variation functionals.
• The course was entitled "Geometric PDE" and described using analytic tools like that of partial differential equations to solve problems in geometry.
• model differential equations like that of the Gaussian curvature equations on compact surfaces, the prescribing curvature equations and the evolution equations related to the curvature flows.

160. Évariste Galois (1811-1832)
• On 25 May and 1 June he submitted articles on the algebraic solution of equations to the Academie des Sciences.
• Galois sent Cauchy further work on the theory of equations, but then learned from Bulletin de Ferussac of a posthumous article by Abel which overlapped with a part of his work.
• Galois then took Cauchy's advice and submitted a new article On the condition that an equation be soluble by radicals in February 1830.
• Galois was invited by Poisson to submit a third version of his memoir on equation to the Academy and he did so on 17 January.
• .as correct as it is deep of this lovely problem: Given an irreducible equation of prime degree, decide whether or not it is soluble by radicals.
• A page from Galois' Memoire sur les conditions de resolubilite des equations par radicaux (published in his collected works in 1897) .

161. Charles René Reyneau (1656-1728)
• A methodical Art was formed (which is what is called Analysis) to find, by known techniques the unknown magnitudes which are sought in the problems from those which are known, giving equations which express the conditions, and the nature, so to speak, of the problems; and allows one to discover the values of the unknown magnitudes in these equations; which gives the resolution of the problems.
• He gave us the method of reducing curves to equations which express their principal properties; and to derive from these equations all the things which we could desire to know about these curves, and, lastly, how to use the curves themselves to solve equations and problems.
• In the book he solves equations, always assuming that the coefficients are positive.
• This means that when giving the solution to a quadratic equation, he had six cases to consider: .
• He simplifies this when he comes to cubic equations, using ± in front of the coefficients.

162. Jean-Baptiste Bélanger (1790-1874)
• Hubert Chanson writes [',' H Chanson, Jean-Baptiste Charles Joseph Belanger (1790-1874), the Backwater Equation and the Belanger Equation, Hydraulic Model Report No.
• The application of the momentum principle to the hydraulic jump is commonly called the Belanger equation, but few know that his original treatise was focused on the study of gradually varied open channel flows (Belanger 1828).
• The originality of Belanger's 1828 essay was the successful development of the backwater equation for steady, one-dimensional gradually-varied flows in an open channel, together with the introduction of the step method, distance calculated from depth, and the concept of critical flow conditions.
• Belanger gave some specific examples in the paper to show the applicability of his equation.
• Belanger provided a stepwise integration of this equation in the simple case of the horizontal aqueduct that had been built recently to bring the waters of the Ourcq River into Paris.
• He made major contributions to teaching at this famous university [',' H Chanson, Development of the Belanger equation and backwater equation by Jean-Baptiste Belanger (1928), J.
• This 1841 work contained the hydraulic jump equation now known as the Belanger equation.
• He published another text, Traite de la dynamique des systemes materiels Ⓣ, in 1866 [',' H Chanson, Development of the Belanger equation and backwater equation by Jean-Baptiste Belanger (1928), J.
• Let us end with the words of Chanson [',' H Chanson, Jean-Baptiste Charles Joseph Belanger (1790-1874), the Backwater Equation and the Belanger Equation, Hydraulic Model Report No.

163. Émile Picard (1856-1941)
• Picard made his most important contributions in the fields of analysis, function theory, differential equations, and analytic geometry.
• He used methods of successive approximation to show the existence of solutions of ordinary differential equations solving the Cauchy problem for these differential equations.
• Starting in 1890, he extended properties of the Laplace equation to more general elliptic equations.
• Picard also discovered a group, now called the Picard group, which acts as a group of transformations on a linear differential equation.

164. James Gregory (1638-1675)
• On the latter topic he had become interested in the problem of solving quintic equations algebraically and made some interesting discoveries on Diophantine problems.
• However, we now summarise these and other contributions in the hope that, despite his reluctance to publish his methods, his remarkable contributions might indeed be more widely understood: Gregory anticipated Newton in discovering both the interpolation formula and the general binomial theorem as early as 1670; he discovered Taylor series more than 40 years before Taylor; he solved Kepler's famous problem of how to divide a semicircle by a straight line through a given point of the diameter in a given ratio (his method was to apply Taylor series to the general cycloid); he gives one of the earliest examples of a comparison test for convergence, essentially giving Cauchy's ratio test, together with an understanding of the remainder; he gave a definition of the integral which is essentially as general as that given by Riemann; his understanding of all solutions to a differential equation, including singular solutions, is impressive; he appears to be the first to attempt to prove that π and e are not the solution of algebraic equations; he knew how to express the sum of the nth powers of the roots of an algebraic equation in terms of the coefficients; and a remark in his last letter to Collins suggests that he had begun to realise that algebraic equations of degree greater than four could not be solved by radicals.
• James Gregory's manuscripts on algebraic solutions of equations .

• The first part of the thesis, entitled Sur une classe d'equations aux derivees partielles du second ordre, du type hyperbolique, a 3 ou 4 variables independantes Ⓣ, dealt with the partial differential equation (1) with limit condition that arise in the two problems: the interior problem and the exterior problem.
• For this problem, he dealt also with the equation (2).
• It was in 1901 that Robert d'Adhemar's first publications were published, namely the mathematical papers Sur une integration par approximations successives Ⓣ and Sur une classe d'equations aux derives partielles du second ordre Ⓣ.
• Although he had been writing philosophy book, he continued to publish mathematical papers such as Sur une equation aux derivees partielles du type hyperbolique Ⓣ (1905) and historical works such as Trois maitres: Ampere, Cauchy, Hermite Ⓣ (1905).
• His first mathematics book Les equations aux derivees partielles a caracteristiques reelles Ⓣ was published in 1907.
• Equations differentielles.
• Equations integrales de M Fredholm et de M Volterra.
• Equations aux derivees partielles du second ordre Ⓣ (1908) and L'equation de Fredholm et les problemes de Dirichlet et de Neumann Ⓣ (1909).
• This book gave numerical methods for solving non-linear equations.
• Equations integrales.
• Equations differentielles et fonctionnnelles Ⓣ was published in 1912 with the second volume Fonctions synectiques, methodes des majorantes.
• Equations aux derivees partielles du premier ordre.

166. Edward Copson (1901-1980)
• Copson studied classical analysis, asymptotic expansions, differential and integral equations, and applications to problems in theoretical physics.
• by Poisson's analytical solution of the equation of wave-motions.
• .The analogue of Kirchhoff's formula, due to Volterra, is derived and an interesting account is given of a method, devised by Marcel Riesz and based on the theory of fractional integration, which provides a powerful method of solving initial value problems for equations like the wave equation.
• In 1975 he published Partial differential equations which covers most of the classical techniques for first and second order linear partial differential equations, giving many examples and applications to physical problems.

167. Sergei Sobolev (1908-1989)
• Sobolev became interested in differential equations, a topic which would dominate his research throughout his life, and even at this stage in his career he produced new results which he published.
• published a number of profound papers in which he put forward a new method for the solution of an important class of partial differential equations.
• Working with Smirnov, Sobolev studied functionally invariant solutions of the wave equation.
• These methods allowed them to find closed form solutions to the wave equation describing the oscillations of an elastic medium.
• By 1935 Sobolev was head of the Department of the Theory of Differential Equations at the Institute.
• In 1958 Sobolev was part of the Soviet delegation to the International Mathematical Union, the delegation being led by Vinogradov, and Sobolev attended the International Congress at Edinburgh that year and gave an invited address on partial differential equations.

• Schrodinger published his two fundamental papers on quantum theory in the spring of 1926 and Fock immediately started to develop the ideas and by the end of the year two of his own important papers on the Schrodinger equation had been published.
• He became interested in the geometrization of the Dirac equation and he published an important paper in 1928 on Dirac's work on distributions.
• the fundamental paper of 1935 in which the full symmetry structure of the hydrogen atom energy levels was shown to be given by the full Lorentz group; and the 1937 paper on the proper time parametrization of the Dirac equation, seminal for the later development of Schwinger's theory of field propagators and for the whole subject of parametrised field theories.
• The reviewer feels that the author has made a major contribution to the understanding of gravitation theory, especially by his insistence on studying the solutions of the field equations and not merely the formal properties of the equations.
• Some we have mentioned but now let us list a few: Fock space; Fock vacuum; the Fock method of quantisation; the Fock proper time method; the Hartree-Fock method; Fock symmetry; the Klein-Fock-Gordon equation; the Fock-Krylov theorem; and Dirac-Fock-Podolsky formalism.

169. Philip Maini (1959-)
• Now, when kicking a football about, I dream of solving maths problems instead! I first saw the power and beauty of mathematics when, in the first year of A levels, my teacher wrote down the equation for simple harmonic motion for a swinging pendulum and I saw how this simple equation could describe everything about the motion of the pendulum.
• Maini attended the conference 'Ordinary and partial differential equations', held in Dundee, Scotland in 1984.
• Analysis of the model equations elucidates the interaction and roles of the model parameters in determining the speed of healing and the shape of the traveling wave solutions which correspond to the migration of cells into the wound during the initial phase of healing.
• Numerical solutions of the model equations also confirm the importance of both migration and mitosis for effective would healing.
• To do that, I use mathematical modelling - I write down mathematical equations to describe what the biologists think is happening.

170. John Colson (1680-1760)
• In 1707 Colson published The universal resolution of cubic and biquadratic equations viz.
• In the paper he gave a method to solve a cubic equation which was similar to that which had been discovered by several other mathematicians.
• This is a quadratic equation in a3, so it can be solved for a3 using the usual formula for a quadratic.
• Colson tested each of these 9 possible solutions to see if it satisfies the original equation, and was able to identify the three actual solutions.
• This paper by Colson was the first to give all three solutions to a cubic equation.
• In the final part of the paper he gives a method to solve cubic and quartic equations using geometric constructions of circles and parabolas.

171. Franz Rellich (1906-1955)
• In this dissertation he generalised the Riemann's integration method, namely the explicit representation of the solution of the initial value problem of a linear hyperbolic differential equation of second order, to the case of such equations any order.
• During the years 1933-34 at Gottingen, Rellich has taught courses on Integral Equations and Spectral Theory (1933) and Partial Differential Equations (1934).
• Another piece of work which brought him international recognition was his study of the Monge-Ampere differential equation of elliptic type which we already mentioned when we looked at his papers published in the period 1932-34.
• He is also known for Rellich's theorem on entire solutions of differential equations which he proved in 1940.

172. Thomas Cherry (1898-1966)
• thesis Differential Equations Of Dynamics was written under guidance from Henry Baker and Ralph Fowler.
• His first papers On the form of the solution of the equations of dynamics, On Poincare's theorem of 'the non-existence of uniform integrals of dynamical equations', and Note on the employment of angular variables in celestial mechanics were all published in 1924 and Some examples of trajectories defined by differential equations of a generalised dynamical type in the following year.
• He undertook research on ordinary differential equations, particularly those arising from dynamics and celestial mechanics, for four years.
• In 1937 he published Topological Properties of the Solutions of Ordinary Differential Equations and in 1947 he published the first part of Flow of a compressible fluid about a cylinder.
• Since the author uses the solutions of Chaplygin, in the form of an infinite series of hypergeometric functions, of the linear second order partial differential equation in the hodograph variables of the potential function, this series diverges for values of the velocity whose speeds exceed the speed at infinity.

173. Frank Smithies (1912-2002)
• There he took courses by G H Hardy on Fourier analysis, John Whittaker on integral equations, and Ebenezer Cunningham on mechanics.
• Smithies graduated in 1933 and began research on integral equations with Hardy at Cambridge.
• He won the Rayleigh Prize in 1935 for an essay on differential equations of fractional order, and was awarded his doctorate for his thesis The Theory Of Linear Integral Equation which he submitted to the University of Cambridge in 1936.
• Smithies early work was on integral equations and in 1958 his text Integral equations was published by Cambridge University Press in their Cambridge Tracts in Mathematics and Mathematical Physics Series.
• the present work is intended as a successor to Maxime Bocher's tract, "An introduction to the study of integral equations" (University Press, Cambridge, 1909).

174. Erhard Schmidt (1876-1959)
• His doctoral dissertation was entitled Entwicklung willkurlicher Funktionen nach Systemen vorgeschriebener Ⓣ and was a work on integral equations.
• Schmidt's main interest was in integral equations and Hilbert space.
• He took various ideas of Hilbert on integral equations and combined these into the concept of a Hilbert space around 1905.
• Hilbert had studied integral equations with symmetric kernel in 1904.
• He showed that in this case the integral equation had real eigenvalues, Hilbert's word, and the solutions corresponding to these eigenvalues he called eigenfunctions.
• Schmidt published a two part paper on integral equations in 1907 in which he reproved Hilbert's results in a simpler fashion, and also with less restrictions.
• In 1908 Schmidt published an important paper on infinitely many equations in infinitely many unknowns, introducing various geometric notations and terms which are still in use for describing spaces of functions and also in inner product spaces.

175. Boris Yakovlevic Bukreev (1859-1962)
• Ermakov was the first to show that some nonlinear differential equations of second order are simply related with linear differential equations of second order.
• He visited Berlin where he heard lectures on the theory of hyperelliptic functions by Karl Weierstrass, lectures on the theory of Abelian functions and linear differential equations by Lazarus Fuchs, and lectures on the theory of numbers from Leopold Kronecker.
• Bukreev determined the conditions for continuity of Fuchsian groups and constructed differential equations corresponding to each of the discontinuous groups.
• Bukreev's work was broad and in addition to the areas of complex functions, differential equations, the theory and application of Fuchsian functions of rank zero, and geometry, he published papers on algebra such as On the composition of groups (1900).
• He taught courses on analysis, differential and integral calculus and their applications to geometry, the theory of integration of differential equations, the theory of series, algebra, and other topics.
• The geodesics as solutions of the Euler equation, Gauss curvature, geodesic curvature; II.

176. Kiyosi Ito (1915-2008)
• Introducing the concept of regularisation, developed by Doob of the United States, I finally devised stochastic differential equations, after painstaking solitary endeavours.
• He created the theory of stochastic differential equations, which describe motion due to random events.
• Among them were On a stochastic integral equation (1946), On the stochastic integral (1948), Stochastic differential equations in a differentiable manifold (1950), Brownian motions in a Lie group (1950), and On stochastic differential equations (1951).
• Stochastic differential equations, called "Ito Formula," are currently in wide use for describing phenomena of random fluctuations over time.
• When I first set forth stochastic differential equations, however, my paper did not attract attention.

177. Thomas Craig (1855-1900)
• One was A General Differential Equation in the Theory of the Deformation of Surfaces which was reprinted from the Journal of the Franklin Institute.
• In the Second Half-Year of 1881-82 Craig taught the following courses: 'Mathematical Seminary' (along with J J Sylvester, Arthur Cayley and William Story); 'Elliptic Functions' (3 lectures each week); 'Elasticity' (3 lectures each week); and 'Partial Differential Equations' (3 lectures each week).
• In the Second Half-Year of 1882-83 Craig's courses were: 'Partial Differential Equations'; 'Elliptic and Theta Functions'; and 'Hydrodynamics'.
• We have mentioned some of Craig's books already but perhaps the best known of his works was A Treatise on Linear Differential Equations published in 1889.
• It is true that some of his lectures on differential equations, on hydrodynamics, and on the theory of functions were very advanced and very difficult; and those lectures could be followed with profit only by the maturest of his students.
• In addition to his contributions to mathematical journals, he published, in 1879, two manuals on the elements of the mathematical theory of fluid motion, and, in 1889, the first volume of a treatise on linear differential equations, a continuation of which was not completed at the time of his death.
• Linear Differential Equations by Thomas Craig .

178. Michel Rolle (1652-1719)
• He published his most important work Traite d'algebre in 1690 on the theory of equations.
• He also used it to solve Diophantine linear equations.
• Let us see how this idea worked: If P(x) = 0 is a given polynomial equation with real roots a and b then he constructs a polynomial P'(x), which he called the 'first cascade,' so that P'(b) = (b - a)Q(b) where Q(x) is a polynomial of lower degree.
• Some basic principles of the calculus and the theory of equations can definitely be traced to their origin as incidental propositions of the method.
• It amplified the concepts of limits of roots of equations, provided the fundamentals from which Maclaurin derived his formula, began modern methods of series for determining roots, and discussed the relationship of imaginary roots in equations and their derivatives.
• Rolle published another important work on solutions of indeterminate equations in 1699, Methode pour resoudre les equations indeterminees de l'algebre.

179. Onorato Nicoletti (1872-1929)
• The other works relate to ordinary differential equations, or to those with partial derivatives also of a higher order than the 2nd, and they all have particular importance for the completion of the results obtained with the method of successive approximations and with that of Riemann as well as for the studies that are taking place on the 2nd order equations of hyperbolic type, in which the Laplace series is finite.
• In the work "On Ordinary Differential Equations" he examines under what conditions the integrals of these equations are continuous functions and derivable from the initial values.
• The work on the transformation of the 2nd order linear differential equations, and the other analogues, demonstrate the talent of the competitor.
• Nicoletti published works in various fields of mathematics, including algebraic analysis, infinitesimal analysis, equations related to Hermitian matrices and differential equations.
• For example, on Hermitian matrices he wrote Sulla caratteristica del determinante di una forma di Hermite Ⓣ (1909), on ordinary differential equations Sugli integrali delle equazioni differenziali ordinarie, considerati come funzioni dei loro valori iniziati Ⓣ (1895) and on partial differential equations Sull'estensione dei metodi di Picard e di Riemann ad una classe di equazioni a derivate parziali Ⓣ (1896).
• Rapidly the young scientist was established after two years of improvement, and after just over a year, teaching in the Technical Institute of Rome, he won with a group of twelve important works, almost all on differential equations, the competition for the chair of Calculus in Modena, where he was nominated in January of 1898.
• A remarkable group of works, forming an organic complex, refers to the theory of partial differential equations, and precisely to extensions of the method of successive approximations and to the theory of transformations; another group refer to that of ordinary differential equations.
• Also important are the works concerning certain classes of equations with real roots, the theory of determinants and matrices, the Weierstrass theorem on the equivalence of two bundles of bilinear forms; this latter work was to be followed by two other memoirs that he could not complete.

180. François Budan (1761-1840)
• Budan is considered an amateur mathematician and he is best remembered for his discovery of a rule which gives necessary conditions for a polynomial equation to have n real roots between two given numbers.
• In the early 19th century F D Budan and J B J Fourier presented two different (but equivalent) theorems which enable us to determine the maximum possible number of real roots that an equation has within a given interval.
• Budan's rule was in a memoir sent to the Institute in 1803 but it was not made public until 1807 in Nouvelle methode pour la resolution des equations numerique d'un degre quelconque Ⓣ.
• If an equation in x has n roots between zero and some positive number p, the transformed equation in (x - p) must have at least n fewer variations in sign than the original.
• He quoted Lagrange to show that it would be useful to give the rules for solving numerical equations entirely by means of arithmetic, referring to algebra only if absolutely necessary.
• Accordingly, the chief concern of Burdan's Nouvelle methode was to give the reader a mechanical process for calculating the coefficients of the transformed equation in (x - p).
• Let us note that Charles-Francois Sturm in his famous paper Memoire sur la resolution des equations numeriques Ⓣ published in 1829 completely solved the problem of determining the number of real roots of an equation on a given interval.

• He considers problems of indeterminate equations of the first degree and trigonometric formulae.
• ','12], [',' K S Shukla, Hindu mathematics in the seventh century as found in Bhaskara I’s commentary on the Aryabhatiya III, Ganita 23 (1) (1972), 57-79','13] and [',' K S Shukla, Hindu mathematics in the seventh century as found in Bhaskara I’s commentary on the Aryabhatiya IV, Ganita 23 (2) (1972), 41-50.','14] Shukla discusses some features of Bhaskara's mathematics such as: numbers and symbolism, the classification of mathematics, the names and solution methods of equations of the first degree, quadratic equations, cubic equations and equations with more than one unknown, symbolic algebra, unusual and special terms in Bhaskara's work, weights and measures, the Euclidean algorithm method of solving linear indeterminate equations, examples given by Bhaskara I illustrating Aryabhata I's rules, certain tables for solving an equation occurring in astronomy, and reference made by Bhaskara I to the works of earlier Indian mathematicians.

182. Olga Arsenievna Oleinik (1925-2001)
• Given Petrovsky's expertise in differential equations, the topology of algebraic curves and surfaces and mathematical physics, it is not difficult to see his influence on the direction that Oleinik's work would take.
• In 1973 she became Head of the Department of Differential Equations at Moscow State.
• The three chapters are: Basic mathematical aspects of the theory of elasticity; Homogenization of the equations of linear elasticity; Composites and perforated materials and Spectral problems in homogenization theory.
• It is self-contained and the reader with background in partial differential equations and continuum mechanics can learn the homogenization techniques developed by Oleinik and her coauthors.
• In 1996 Oleinik published Some asymptotic problems in the theory of partial differential equations.
• Much of the book is devoted to the study of the asymptotic behaviour of solutions to nonlinear elliptic second-order equations.
• Oleinik considers equations satisying Dirichlet boundary conditions and ones which satisfy Neumann boundary conditions.
• Oleinik also studies the homogenization problem for linear elliptic equations in domains with the property that half is perforated and half contains no holes.
• This book is a vast treasury of rigorous mathematical results about the Prandtl systems of partial differential equations in fluid dynamics.
• The Prandtl equations were devised early in this century as a simpler replacement for the Navier-Stokes equations to describe viscous laminar fluid flows near boundaries to which the fluid adheres.
• These replacement equations have a quite different mathematical character than the Navier-Stokes equations, and as one can easily see from this book, the theory goes along very different lines.

183. Richard Bellman (1920-1984)
• His doctoral dissertation on the stability of differential equations was concerned with the behaviour of the solutions of real differential equations as the independent variable t tends to infinity.
• Results from his dissertation appeared in the book Stability theory of differential equations which he published in 1953.
• He went on to introduce Markovian decision problems in 1957 and in 1958 he published his first paper on stochastic control processes where he introduced what is today called the Bellman equation.
• These include, in addition to those already mentioned: A Survey of the Theory of the Boundedness, Stability, and Asymptotic Behavior of Solutions of Linear and Nonlinear Differential and Difference Equations (1949); A survey of the mathematical theory of time-lag, retarded control, and hereditary processes (1954); Dynamic programming of continuous processes (1954); Dynamic programming (1957); Some aspects of the mathematical theory of control processes (1958); Introduction to matrix analysis (1960); A brief introduction to theta functions (1961); An introduction to inequalities (1961); Adaptive control processes: A guided tour (1961); Inequalities (1961); Applied dynamic programming (1962); Differential-difference equations (1963); Perturbation techniques in mathematics, physics, and engineering (1964); and Dynamic programming and modern control theory (1965).
• After his death in 1984 his books continued to be published such as Partial differential equations (1985), Selective computation (1985), Methods in approximation (1986), and Wave propagation: An invariant imbedding approach (1986).

184. Ralph Fowler (1889-1944)
• Early in his career, after receiving his degree, Fowler took to examining the behavior of the solutions to certain second-order differential equations.
• In particular, he studied Emden's differential equation: .
• Sir Arthur Eddington had originally shown that the equilibrium of gaseous stars could be found using the above equation with n = 3.
• He rightly deduced Emden's equation must have other solutions.
• The resulting general equation, which had considerable later influence on stellar astrophysics, was: .
• These ions are closely packed leaving the free electrons to form a degenerate gas which Fowler described as "like a gigantic molecule in its lowest state." The equilibrium of the white dwarfs was later found to be described by a solution to Emden's equation as generalized by Fowler in the above equation with n = 3/2.

185. István Feny (1917-1987)
• The last topic in the book is the theory of non-linear ordinary differential equations, beginning with questions of existence consequences and stability.
• The third volume published in 1980, although still presenting methods for engineers, is more involved with one of Fenyő's main research topics, namely integral equations.
• The second section, which is over a quarter of the book, discusses linear integral equations.
• Amongst the topics covered are Volterra integral equations and their relation with ordinary differential equations, Fredholm equations, self-conjugate and non-self-conjugate integral operators, and the associated eigenvalue theory.
• The third section is on applications of integral equations.
• Other books by Fenyő on integral equations are Integral equations - a book of problems (Hungarian) (1957), and the four volume work (written with H-W Stolle) Theorie und Praxis der linearen Integralgleichungen Ⓣ (1982, 1983, 1983, 1984).
• These three volumes complete the encyclopaedic work (roughly 1700 pages) by Fenyő and Stolle on the theory and application of linear integral equations.
• Their thesis is that the classical theory of linear integral equations produced many ideas for the later development of the theory of linear operators, and in turn functional analysis has helped the further development of integral equations.

• These courses were: Higher Algebra, Theory of functions, Differential Equations, Integral Equations, Differential Geometry, Projective geometry, Variational Calculus, Operational Calculus, and Probability Theory.
• His research interests were in applications of mathematics and he studied periodic and asymptotic solutions of systems of differential equations, applications of nonlinear differential equations in electrical engineering, nonlinear oscillations and resistance, and electrostatic potential.
• Here are a few of these papers which we quote as examples of his contributions: The position of a system of three consecutively connected mathematical pendulums in one plane in their periodic motion about a position of stable equilibrium (Bulgarian) (1954); Sur les solutions periodiques et asymptotiques du mouvement autour de l'etat d'equilibre d'un systeme de N-pendules physiques successivement lies dans un plan Ⓣ (1955); (with George Boyadjiev) Existenz periodischer Bewegungen eines n-fachen Pendels im Falle, dass einige Wurzeln seiner charakteristischen Gleichung ein Vielfaches einer anderen sind Ⓣ (1959); Periodic and asymptotic motions of compound physical pendula coupled in a vertical plane (Russian) (1963); (with George Boyadjiev) Periodic solutions of an autonomous system and their application to autogenerators with n oscillating circles (Bulgarian) (1964); (with George Boyadjiev) The periodic solutions and the stability of a quasilinear autonomous system of differential equations in the case of multiple roots of the fundamental equations (Bulgarian) (1966); (with Georgi Boyadjiev) On the periodic solutions of an autonomous system of differential equations of second order in a critical case (1970); (with Spas Manolov) On a certain algebraic condition for periodic trajectories in the case of autonomous systems of differential equations with polynomial nonlinearities of a certain class (Bulgarian) (1973); and Une condition necessaire et suffisante pour l'existence de solutions periodiques d'un systeme d'equations differentielles de second ordre Ⓣ (1975).
• We mention two in particular, namely the Seminar on Differential Equations at the Institute of Mechanical and Electrical Engineering and the National Colloquium of Mathematics at the Union of Bulgarian Mathematicians.
• With great taste, precision and enthusiasm he prepare a detailed report on the activities and achievements of Bulgarian mathematicians who were specialists in ordinary and partial differential equations, which delivered at the Conference on Differential Equations and Applications, held in Rousse, Bulgaria, at the end of June 1975.
• He was elected to the Bulgarian Academy of Sciences in 1967, becoming the first expert on differential equations to be elected to the Academy.

187. John Carr (1948-2016)
• in 1974 for his thesis The Asymptotic Behaviour of the Solutions of Some Linear Functional Differential Equations.
• at the University of Oxford at the same time as Carr and her thesis was on a similar topic to that of Carr, namely Some topics in functional differential equations (1973).
• Carr and Dyson published three joint papers in 1974-1975, one being in the proceedings of the conference Ordinary and partial differential equations held at the University of Dundee, Scotland, in 1974 and the other two in the Proceedings of the Royal Society of Edinburgh.
• The purpose of the lectures was to give an introduction to the applications of centre manifold theory to differential equations.
• Dynamic bifurcation theory is concerned with topological changes in the nature of the solutions of differential equations as parameters are varied.
• Ordinary differential equations; and The application of centre manifolds to amplitude expansions.
• Carr published many important papers throughout his career and we will only give here the titles of a small number: (with Oliver Penrose) The Becker-Doring cluster equations: basic properties and asymptotic behaviour of solutions (1986); (with John M Ball) Coagulation-fragmentation dynamics (1987); (with John M Ball) Asymptotic behaviour of solutions to the Becker-Doring equations for arbitrary initial data (1988); (with John M Ball) The discrete coagulation-fragmentation equations: existence, uniqueness, and density conservation (1990); Asymptotic behaviour of solutions to the coagulation-fragmentation equations.
• Nonlinear differential equations and dynamical systems is a vast area and practitioners include applied mathematicians, analysts and others in science and engineering.
• The main topic will be the study of the qualitative and geometric theory of nonlinear differential equations and dynamical systems.

188. Dimitri Fedorovich Egorov (1869-1931)
• He was appointed an assistant lecturer at Moscow University on 27 January 1894, obtaining his Master's Degree in October 1899 for his thesis Second-order partial differential equations in two independent variables which he had defended on 22 September 1899.
• Egorov also worked on integral equation publishing significant papers such as Sur quelques points de la theorie des equations integrates a limites fixes and Sur la theorie des equations integrates au noyau symmetrique which were both published in 1928.
• In the following year he published lecture notes under the title Integration of differential equations.
• At Moscow University, before his appointment as a professor, he taught courses on the synthetic theory of conics, number theory, the geometrical theory of partial differential equations, the theory of determinants, and the theory of binary forms.
• After he was appointed as a professor, he taught courses on differential geometry, the integration of differential equations, integral equations, the calculus of variations, number theory, and the theory of surfaces.

189. Norman Levinson (1912-1975)
• Norman decided to shift his field from gap and density theorems to non-linear differential equations, both ordinary and partial.
• I recall our talking about this decision in 1940, and how difficult is was to move into this new field, and how hard Norman worked over a period of two or three years before he felt that he had enough mastery to obtain substantial results in this field; but this mastery he did achieve, and his outstanding contributions to non-linear differential equations were recognised officially in 1954 when the American Mathematical Society awarded Norman the Bocher Prize.
• This was Theory of ordinary differential equations (written jointly with Earl Coddington) which [',' J A Nohel and D H Sattinger (eds.), Norman Levinson : Selected papers of Norman Levinson (2 Vols.) (Boston, MA, 1998).','2]:- .
• The deep and original ideas of Norman Levinson have had a lasting impact on fields as diverse as differential and integral equations, harmonic, complex and stochastic analysis, and analytic number theory during more than half a century.
• In other topics, Levinson provided the foundation for a rigorous theory of singularly perturbed differential equations.
• He also made fundamental contributions to inverse scattering theory by showing the connection between scattering data and spectral data, thus relating the famous Gelfand-Levitan method to the inverse scattering problem for the Schrodinger equation.

190. Karen Uhlenbeck (1942-)
• Uhlenbeck is a leading expert on partial differential equations and describes her mathematical interests as follows:- .
• I work on partial differential equations which were originally derived from the need to describe things like electromagnetism, but have undergone a century of change in which they are used in a much more technical fashion to look at the shapes of space.
• I did some very technical work in partial differential equations, made an unsuccessful pass at shock waves, worked in scale invariant variational problems, made a poor stab at three dimensional manifold topology, learned gauge field theory and then some about applications to four dimensional manifolds, and have recently been working n equations with algebraic infinite symmetries.
• She described advances in geometry that have been achieved through the study of systems of nonlinear partial differential equations.
• Among other things, she sketched some aspects of Simon Donaldson's work on the geometry of four-dimensional manifolds, instantons - solutions, that is, of a certain nonlinear system of partial differential equations, the self-dual Yang-Mills equations, which were originally introduced by physicists in the context of quantum field theory.
• She has also served on the editorial boards of many journals; a complete list to date is Journal of Differential Geometry (1979-81), Illinois Journal of Mathematics (1980-86), Communications in Partial Differential Equations (1983- ), Journal of the American Mathematical Society (1986-91), Ergebnisse der Mathematik (1987-90), Journal of Differential Geometry (1988-91), Journal of Mathematical Physics (1989- ), Houston Journal of Mathematics (1991- ), Journal of Knot Theory (1991- ), Calculus of Variations and Partial Differential Equations (1991- ), Communications in Analysis and Geometry (1992- ).
• For her many pioneering contributions to global geometry that resulted in advances in mathematical physics and the theory of partial differential equations.
• Karen Uhlenbeck is a distinguished mathematician of the highest international stature, specialising in differential geometry, non-linear partial differential equations and mathematical physics.

191. Paul du Bois-Reymond (1831-1889)
• However, he continued to undertake research into applied mathematics and, as a consequence, became more and more involved with the theory of partial differential equations.
• In this work he generalised Monge's idea of the characteristic of a partial differential equation from second order equations to third order equations.
• Du Bois-Reymond's work is almost exclusively on calculus, in particular partial differential equations and functions of a real variable.
• The standard technique to solve partial differential equations used Fourier series but Cauchy, Abel and Dirichlet had all pointed out problems associated with the convergence of the Fourier series of an arbitrary function.

192. John Brinkley (1766-1835)
• As examples of Brinkley's mathematical papers we list the following seven papers (many of which have long descriptive titles): A General Demonstration of the Property of the Circle Discovered by Mr Cotes, Deduced from the Circle Only (1800); A Method of Expressing, When Possible, the Value of One Variable Quantity in Integral Powers of Another and Constant Quantities, Having Given Equations Expressing the Relation of These Variable Quantities.
• In Which Is Contained the General Doctrine of Reversion of Series, of Approximating to the Roots of Equations, and of the Solution of Fluxional Equations by Series (1800); General Demonstrations of the Theorems for the Sines and Cosines of Multiple Circular Arcs, and Also of the Theorems for Expressing the Powers of Sines and Cosines by the Sines and Cosines of Multiple Arcs; to Which Is Added a Theorem by Help Whereof the Same Method May Be Applied to Demonstrate the Properties of Multiple Hyperbolic Areas (1800); On Determining Innumerable Portions of a Sphere, the Solidities and Spherical Superficies of Which Portions Are at the Same Time Algebraically Assignable (1802); A Theorem for Finding the Surface of an Oblique Cylinder, with Its Geometrical Demonstration.
• Also, an Appendix, Containing Some Observations on the Methods of Finding the Circumference of a very Excentric Ellipse; including a Geometrical Demonstration of the Remarkable Property of Elliptic Arcs Discovered by Count Fagnani (1803); An Investigation of the General Term of an Important Series in the Inverse Method of Finite Differences (1807); and Observations Relative to the Form of the Arbitrary Constant Quantities, That Occur in the Integration of Certain Differential Equations; and, Also, in the Integration of a Certain Equation of Finite Differences (1818).
• as the author both of a practical method of determining longitude and as a mathematician who had contributed a new method of solving equations.

193. Matthew O'Brien (1814-1855)
• I confess no more than this - that there is an error in the equations, which error has never been propagated to other parts of my writings ..
• Discussing O'Brien's 1846 paper On a new notation for expressing various conditions and equations in geometry, mechanics, and astronomy, Gordon Charles Smith writes [',' G C Smith, M O’Brien and vectorial mathematics, Historia Mathematica 9 (1982), 172-190.','6]:- .
• O'Brien begins by setting out the fundamental equations of motion of a rigid body ..
• [These sections] contain an application of these equations to computing the solar precession and nutation.
• In a second 1847 paper On the symbolic equation of vibratory motion of an elastic medium whether crystallized or uncrystallized he attempts to give the equations:- .

194. Pierre Verhulst (1804-1849)
• He received his doctorate on 3 August 1825 after only three years study for his thesis De resolutione tum algebraica, tum lineari aequationum binominalium Ⓣ in which he studied the reduction of binomial equations.
• Quetelet does not seem to have appreciated Verhulst's most important contribution, however, namely his work on the logistic equation and logistic function.
• In the paper Verhulst argued against the model for population growth that Quetelet had proposed and instead proposed a model with a differential equation now known as the logistic equation.
• He named the solution to the equation he had proposed in his 1838 paper the 'logistic function'.
• In this last paper, Verhulst put forward some criticisms of his own model of population growth and this, together with Quetelet's criticisms in his obituary of Verhulst [',' A Quetelet, Pierre Francois Verhulst, Annuaire de l’Academie royale des sciences de Belgique 16 (1850), 97-124.','13], led to Verhulst's logistic equation being ignored for many years until the work of Raymond Pearl and Lowell Reed in 1920.

195. Mauro Picone (1885-1977)
• In this period he developed research on ordinary differential equations and partial derivatives.
• three different topics: (i) boundary value problems for second order linear ordinary differential equations, for which Picone developed his well-known "identity", and the subsequent extension of these results to second order linear partial differential equations of elliptic and parabolic types; (ii) partial differential equations of hyperbolic type (in two independent variables), for which Picone studied problems generalizing Goursat's problem; (iii) research on differential geometry in the direction set by L Bianchi, with particular attention to the characterization of the ds2 of a ruling and to W congruences.
• The work undertaken by the Institute included functional analysis, partial differentiation, integral equations, calculus of variations, special functions, probability theory, rational mechanics and mathematical physics.
• Resulting from this were Picone's results on a priori bounds for the solutions of ordinary differential equations, as well as for those of linear partial differential equations of elliptic type and parabolic type for which the bound is obtained by means of the boundary data and the known terms; these results are contained in his well-known 'Notes on higher analysis' (Italian) a volume published in 1940 and which was, for its time, "truly avant-garde".
• Gaetano Fichera highlights Picone's 1936 memoir which contains a characterization of a large class of linear partial differential equations whose solutions enjoy mean-value properties termed "integral properties" by Picone; using this theory Picone reconstructed M Nicolescu's theory of polyharmonic functions.
• However, the works which led to the broadest and most important research are those based on the translation of boundary value problems for linear partial differential equations into systems of Fischer-Riesz integral equations; this method, whose object is the numerical calculation of the solutions, is similar to that of subsequent authors, who considered weak solutions of the same problems.
• Some of his most important books which Picone published during his years in Rome are: Appunti di Analisi superiore Ⓣ (1940), which studies harmonic functions, Fourier, Laplace and Legendre series and the equations of mathematical physics; Lezioni di Analisi funzionale Ⓣ (1946), which concerns the calculus of variations; Teoria moderna dell'integrazione delle funzioni Ⓣ (1946), containing a detailed discussion of the r-dimensional Stieltjes integrals; (with Tullio Viola) Lezioni sulla teoria moderna dell'integrazione Ⓣ (1952), which is basically the previous work by Picone with three extra chapters by Viola; and (with Gaetano Fichera) Trattato di Analisi matematica Ⓣ (Vol 1, 1954, Vol 2, 1955), which puts into a treatise Picone's way of teaching calculus particularly slanted towards the applications studied at the Institute for Applied Calculus.

196. Nikolai Nikolaevich Bogolyubov (1909-1992)
• He wrote his first scientific paper On the behavior of solutions of linear differential equations at infinity (Russian) in 1924.
• The works of his first period, some of which were carried out by him jointly with his teacher N M Krylov, deal with direct methods of the calculus of variations, to the theory of nearly-periodic functions and approximate solutions of boundary-value differential equations.
• Bogolyubov found methods to asymptotically integrate non-linear equations modelling oscillating systems [',' V S Vladimirov, D N Zubarev, B V Medvedev, Yu A Mitropolskii, O S Parasyuk and M K Polivanov, Nikolai Nikolaevich Bogolyubov (on the occasion of his sixtieth birthday), Russian Math.
• Examples of physical systems are given which lead to the type of equation considered in the monograph.
• Moreover, general statements of methods for solving equations are illustrated by the explicit solution of examples.
• Bogolyubov himself completed a series of brilliant papers on the theory of stability of a plasma in a magnetic field and on the theory and applications of the kinetic equations, and he began his construction of axiomatic quantum field theory.

197. Lipman Bers (1914-1993)
• Here Bers began work on the problem of removability of singularities of non-linear elliptic equations.
• The nonparametric differential equation of minimal surfaces may be considered the most accessible significant example revealing typical qualities of solutions of non-linear partial differential equations.
• The author sets as his goal the development of a function theory for solutions of linear, elliptic, second order partial differential equations in two independent variables (or systems of two first-order equations).
• One of the chief stumbling blocks in such a task is the fact that the notion of derivative is a hereditary property for analytic functions while this is clearly not the case for solutions of general second order elliptic equations.

198. Ivar Bendixson (1861-1935)
• Bendixson also made interesting contributions to algebra when he investigated the classical problem of the algebraic solution of equations.
• Abel had shown that the general equation of degree five could not be solved by radicals, while Galois had developed Galois theory which determined which equations could be solved by radicals.
• Bendixson returned to Abel's original contribution and showed that Abel's methods could be extended to describe precisely which equations could be solved by radicals.
• In examining periodic solutions of differential equations Bendixson used methods based on continued fractions.
• The analysis problem which intrigued Bendixson more than all others was the investigation of integral curves to first order differential equations, in particular he was intrigued by the complicated behaviour of the integral curves in the neighbourhood of singular points.

199. Thomas Harriot (1560-1621)
• He introduced a simplified notation for algebra and his fundamental research on the theory of equations was far ahead of its time.
• As an example of his abilities to solve equations, even when the roots are negative or imaginary, we reproduce his solution of an equation of degree 4.
• As we have seen from the example above, Harriot did outstanding work on the solution of equations, recognising negative roots and complex roots in a way that makes his solutions look like a present day solution.
• This is a major step forward in understanding which Harriot then carried forward to equations of higher degree.
• History Topics: Quadratic, cubic and quartic equations .

200. Andrei Tikhonov (1906-1993)
• His first-class achievements in topology and functional analysis, in the theory of ordinary and partial differential equations, in the mathematical problems of geophysics and electrodynamics, in computational mathematics and in mathematical physics are all widely known.
• He defended his habilitation thesis in 1936 on Functional equations of Volterra type and their applications to mathematical physics.
• The thesis applied an extension of Emile Picard's method of approximating the solution of a differential equation and gave applications to heat conduction, in particular cooling which obeys the law given by Josef Stefan and Boltzmann.
• Thus, his research on the Earth's crust lead to investigations on well-posed Cauchy problems for parabolic equations and to the construction of a method for solving general functional equations of Volterra type.
• However, in 1948 he began to study a new type of problem when he considered the behaviour of the solutions of systems of equations with a small parameter in the term with the highest derivative.

201. Gabriel Cramer (1704-1752)
• After giving the number of arbitrary constants in an equation of degree n as n2/2 + 3n/2, he deduces that an equation of degree n can be made to pass through n points.
• Taking n = 5 he gives an example of finding the five constants involved in making an equation of degree 2 pass through 5 points.
• This leads to 5 linear equations in 5 unknowns and he refers the reader to an appendix containing Cramer's rule for their solution.
• He states a theorem by Maclaurin which says that an equation of degree n intersects an equation of degree m in nm points.

202. Mark Aronovich Naimark (1909-1978)
• With Krein, Naimark worked on applying Bezout's determinant to the problem of separating the roots of an algebraic equation.
• The two collaborated in writing three papers on this topic: Uber eine Transformation der Bezoutiante, die zum Sturmschen Satze fuhrt Ⓣ (1933); On the application of Bezoutians to the separation of the roots of algebraic equations (1935); and The method of symmetric and hermitian forms in the theory of the separation of the roots of algebraic equations (1936).
• Here he regularly gave courses in mathematical analysis, partial differential equations and functional analysis, he also supervised a group of post-graduate students and organized research seminars.
• We have already noted that Naimark's first work was on the separation of roots of algebraic equations but, once he had established himself in Moscow, he worked on functional analysis and group representations.
• For the pure mathematician it is a systematic treatment of the Lorentz groups in the classical tradition; for the theoretical physicist the long final chapter on invariant equations is of deep interest; for the social historian this Russian account of the theory of the Lorentz groups reveals the isolation of Russian mathematicians from the work of their Western colleagues, the same isolation manifest in Russian music and literature.

203. Richard Tapia (1939-)
• in 1966 and then, in the following year submitted his thesis A Generalization of Newton's Method with an Application to the Euler-Lagrange Equation which led to the award of a Ph.D.
• During this time he began to publish articles, the first one An application of a Newton-like method to the Euler-Lagrange equation in 1969 based on the work of his doctoral thesis.
• In it Tapia considered the solution of the equation P(x) = 0, where P is a nonlinear mapping between Banach spaces.
• He used Newton-like iterations to solve the generalized Euler-Lagrange equation of the calculus of variations.
• It is also shown that this procedure can be applied to a class of two point boundary value problems containing the Euler-Lagrange equation for simple variational problems and most second order ordinary differential equations.

204. Martin Kruskal (1925-2006)
• An important paper on astronomy was Maximal extension of Schwarzschild's metric (1960) which showed that, using what are now called Kruskal coordinates, certain solutions of the equations of general relativity which are singular at the origin are not singular away from the origin, so allowing the study of black holes.
• Kruskal's later work studied soliton equations, asymptotic analysis, and surreal numbers.
• He was led to asymptotic analysis in his plasma physics studies and from there to solutions of Hamiltonian equations as in Asymptotic theory of Hamiltonian and other systems with all solutions nearly periodic (1962).
• Kruskal's important paper (written jointly with Clifford S Gardner, John M Greene and Robert M Miura) Korteweg-de Vries equation and generalizations.
• Before it, there was no general theory for the exact solution of any important class of nonlinear differential equations.
• For his influence as a leader in nonlinear science for more than two decades as the principal architect of the theory of soliton solutions of nonlinear equations of evolution.

• For his Master's thesis Steklov worked on the equations of a solid body moving in an ideal non-viscous fluid.
• There were four cases to be considered in integrating the equations which arose from this problem, and two of these cases had been solved by Clebsch in 1871.
• Began lecturing at the University on the integration of partial differential equations.
• His lecture course on the integration of partial differential equations was to third year students and the lectures went on until April 1909.
• Finished my lectures on integration of equations.
• In addition to the work for his master's thesis and his doctoral thesis referred to above, he reduced problems to boundary value problems of Dirichlet type where Laplace's equation must be solved on a surface.

206. Gianfranco Cimmino (1908-1989)
• Cimmino was only nineteen years old when he graduated with his thesis on approximate methods of solution for the heat equation in 2-dimensions, but he was appointed as an assistant to Picone who held the chair of analytical geometry at the University of Naples.
• Some of Cimmino's most remarkable papers date to the period 1937-38 and concern the theory of partial differential equations of elliptic type.
• Towards the end of that period, Professor Cimmino devised a numerical method for the approximate solution of systems of linear equations that he reminded me of in these days, following the recent publication by Dr Cesari ..
• We have seen that Cimmino made contributions to partial differential equations of elliptic type and to computing approximate solutions to systems of linear equations.
• It is also interesting to observe that Cimmino's impact on his main research area, the theory of partial differential equations, while non-negligible, has not been as great and as lasting as his work in numerical mathematics.

207. Camille Jordan (1838-1922)
• The second part entitled Sur des periodes des fonctions inverses des integrales des differentielles algebriques Ⓣ was on integrals of the form ∫n u dz where u is a function satisfying an algebraic equation f (u, z) = 0.
• Volumes 1 and 2 contain Jordan's papers on finite groups, Volume 3 contains his papers on linear and multilinear algebra and on the theory of numbers, while Volume 4 contains papers on the topology of polyhedra, differential equations, and mechanics.
• He applied his work on classical groups to determine the structure of the Galois group of equations whose roots were chosen to be associated with certain geometrical configurations.
• His work on group theory done between 1860 and 1870 was written up into a major text Traite des substitutions et des equations algebraique Ⓣ which he published in 1870.
• The publication of Traite des substitutions et des equations algebraique Ⓣ did not mark the end of Jordan's contribution to group theory.
• Generalising a result of Fuchs on linear differential equations, Jordan was led to study the finite subgroups of the general linear group of n × n matrices over the complex numbers.
• Although given Jordan's work on matrices and the fact that the Jordan normal form is named after him, the Gauss-Jordan pivoting elimination method for solving the matrix equation Ax= b is not.

208. Mikhail Alekseevich Lavrent'ev (1900-1980)
• For example, he applied variational properties of conformal mappings and reduced the important problem of flow around a wing to the solution of a singular integral equation of the first kind.
• for his work on differential equations in 1982.
• His outstanding scientific results in mathematics and its applications substantially affected the development of the theory of functions of complex variables, theory of differential equations, hydrodynamics, theory of motion of underground water, theory of long waves, dynamic stability, theory of cumulation, and many other fields of science and engineering.
• In the 1940s he developed the theory of quasi-conformal mappings which gave a new geometrical approach to partial differential equations.
• Other topics where he made substantial contributions were the theory of sets, the general theory of functions, and the theory of differential equations.

209. Gertrude Blanch (1897-1996)
• For the Mathieu equation y" + (a - 2 q cos 2x)y = 0, it is well known that certain values of a, described as characteristic values, lead to periodic solutions.
• Among other papers that Blanch wrote before moving to Wright Patterson Air Force Base were: (with Roselyn Siegel) Table of modified Bernoulli polynomials (1950), On the numerical solution of equations involving differential operators with constant coefficients (1952), On the numerical solution of parabolic partial differential equations (1953) and (with Henry E Fettis) Subsonic oscillatory aerodynamic coefficients computed by the method of Reissner and Haskind (1953).
• She continued to publish on Mathieu functions with D S Clemm after retiring, publishing the paper The double points of Mathieu's differential equation (1969) and the book Mathieu's equation for complex parameters.

210. Marcel Riesz (1886-1969)
• Marcel Riesz's interests ranged from functional analysis to partial differential equations, mathematical physics, number theory and algebra.
• Riesz broadened his range of interests during the 1930 when he became interested in potential theory and in partial differential equations.
• He was motivated by wave propagation and in particular Dirac's relativistic equation for the electron.
• In 1949, Riesz published a 223 page paper L'integrale de Riemann-Liouville et le probleme de Cauchy Ⓣ in which he introduced a multiple integral of Riemann-Liouville type and showed how important this idea is in the theory of the wave equation.
• In Problems related to characteristic surfaces Riesz extended these ideas to obtain the solution of the wave equation for a very general class of characteristic boundaries.

211. Alexandre-Theophile Vandermonde (1735-1796)
• Vandermonde's four mathematical papers, with their dates of publication by the Academie des Sciences, were Memoire sur la resolution des equations Ⓣ (1771), Remarques sur des problemes de situation Ⓣ (1771), Memoire sur des irrationnelles de differents ordres avec une application au cercle Ⓣ (1772), and Memoire sur l'elimination Ⓣ (1772).
• The first of these four papers presented a formula for the sum of the mth powers of the roots of an equation.
• The paper also shows that if n is a prime less than 10 the equation xn - 1 = 0 can be solved in radicals.
• Vandermonde's real and unrecognised claim to fame was lodged in his first paper, in which he approached the general problem of the solubility of algebraic equations through a study of functions invariant under permutations of the roots of the equation.
• The reason for this strong claim by Muir is that, although mathematicians such as Leibniz had studied determinants earlier than Vandermonde, all earlier work had simply used the determinant as a tool to solve linear equations.

212. Leonid Andreevich Pastur (1937-)
• Here we only mention the early papers [(with M M Benderskij) 'On the spectrum of the one-dimensional Schrodinger equation with a random potential' (1970), 'On the Schrodinger equation with a random potential' (1971), 'On the distribution of the eigenvalues of the Schrodinger equation with a random potential' (1972), 'Behaviour of some Wiener integrals as t → infinity and the density of states of Schrodinger equations with random potential' (1977), (with I Ya Goldsheid and S Molchanov) 'A pure point spectrum of the stochastic one-dimensional Schrodinger operator' (1977), and 'Spectral properties of disordered systems in the one-body approximation' (1980)], his survey articles ['Spectra of random self-adjoint operators' (1973), and 'Spectral properties of random self-adjoint operators and matrices (a survey)' (1999)] and the monographs [(with I M Lifshits and S A Gredeskul) 'Introduction to the theory of disordered systems' (1982), and (with A Figotin) 'Spectra of random and almost-periodic operators' (1992)].
• We should also note that he has served on the editorial boards of many journals: the International Journal of Low Temperature Physics (1994-); the Journal of Statistical Physics (1987-1989, 1993-1996); Mathematical Physics, Analysis and Geometry (1994-); the Ukrainian Mathematical Journal (1992-); Selecta Matematica Sovetica (1988-1995); Random Operators and Stochastic Equations (1992-); Markov Processes and Related Fields (1999-); and Geometrical and Functional Analysis (2001-).

213. Ludwig Schläfli (1814-1895)
• For a given system of n equations of higher degree with n unknowns, I take a linear equation with undetermined coefficients a, b, c, ..
• The work concluded with an examination of the class equation of third degree curves.
• Other papers which he published investigate a variety of topics such as partial differential equations, the motion of a pendulum, the general quintic equation, elliptic modular functions, orthogonal systems of surfaces, Riemannian geometry, the general cubic surface, multiply periodic functions, and the conformal mapping of a polygon on a half-plane.

214. Joseph Raphson (1668-1712)
• Mr Halley related that Mr Raphson had Invented a method of Solving all sorts of Equations, and giving their Roots in Infinite Series, which Converge apace, and that he had desired of him an Equation of the fifth power to be proposed to him, to which he returned Answers true to Seven Figures in much less time than it could have been effected by the Known methods of Vieta.
• This method invented by Raphson and described in his book Analysis aequationum universalis Ⓣ is now called the Newton method (or the Newton-Raphson method) for approximating the roots of an equation.
• Mr Raphson's Book was this day produced by E Halley, wherein he gives a Notable Improvement of the method of Resolution of all sorts of Equations Showing how to Extract their Roots by a General Rule, which doubles the known figures of the Root known by each Operation, So that by repeating 3 or 4 times he finds them true to Numbers of 8 or 10 places.
• Newton-Raphson method of solving equations .

215. Pascual Jordan (1902-1980)
• The teaching of physics at the Technische Hochschule disappointed Jordan and he studied mostly mathematics taking courses on differential equations, methods of integration, and algebra.
• In particular he enrolled in Richard Courant's differential equations course and Courant quickly realised that he had an exceptionally talented student.
• This paper contains the famous pq - qp equation, the first appearance of this fundamental quantum theory equation.
• He had never worked in fluid dynamics, but rather than read books as I did, he proceeded to derive the equations of motion of supersonic flows.

216. Maurice d'Ocagne (1862-1938)
• Nomography consists in the construction of graduated graphic tables, nomograms, or charts, representing formulas or equations to be solved, the solutions of which were provided by inspection of the tables.
• These papers by d'Ocagne included Nomographie Ⓣ; les Calculs usuels effectues au moyen des abaques Ⓣ (1891); Le Calcul simplifie par les procedes mecaniques et graphiques Ⓣ (1894); Sur la representation monographique des equations du second degre a trois variables Ⓣ (1896); Theorie des equations representables par trois systemes lineaires de points cotes Ⓣ (1897); and Application de la methode nomographique la plus generale, resultant de la superposition de deux plans, aux equations a trois et a quatre variables Ⓣ (1898).
• If one makes a system of geometric elements (points or lines) correspond to each of the variables connected by a certain equation, the elements of each system being numbered in terms of the values of the corresponding variable, and if the relationship between the variables established by the equation may be translated geometrically into terms of a certain relation of position, easy to set up between the corresponding geometric elements, then the set of elements constitutes a chart of the equation considered.
• This is the theory of charts, that is to say the graphical representation of mathematical laws defined by equations in any number of variables, which is understood today under the name Nomography.

217. Charles Noble (1867-1962)
• On 14 August 1907 Noble was in Zurich when he submitted his paper Singular points of a simple kind of differential equation of the second order to the Bulletin of the American Mathematical Society.
• In a series of four memoirs in the 'Journal de Mathematiques', Poincare has, among other things, discussed the topology of curves defined by ordinary differential equations of a simple character.
• In a recent course of lectures Hilbert laid considerable stress on the importance of these results and exhibited an elegant method for obtaining them in the case of a differential equation of the form dy/dx = (cx + dy)/(ax + by).
• In the following paper I have shown how the same method can be used for an ordinary differential equation of the second order.
• Among the papers Noble published, after the ones we mentioned above, were Characteristics of two partial differential equations of order one (1911) and Retention of a salt solution in a tank of flowing water (1922).

218. Karl Heun (1859-1929)
• From 1886 to 1889 he lectured at the University of Munich on topics like: the theory of rational functions and their integrals, the theory of linear differential equations, introduction to the theory of linear substitutions and the general theory of differential equations.
• The Heun equation is a second order linear differential equation of the Fuchsian type with four singular points.
• It generalizes the hypergeometric differential equation which has three singular points, and is used today in mathematical physics, e.g.

219. Pavel Krejí (1954-)
• His next papers were On solvability of equations of the 4th order with jumping nonlinearities (1983), Hard implicit function theorem and small periodic solutions to partial differential equations (1984) and Periodic solutions of a class of abstract nonlinear equations of the second order (1985).
• In this thesis he investigated the existence of periodic solutions of Maxwell's equations in nonlinear media in the Sobolev spaces of divergence-free vector functions in three dimensions.
• He returned to Prague in January 2001 and spent three years there as leader of the 'Evolution equations' research group and Head of the Department of Evolution Differential Equations.
• Most of these papers discuss problems associated with hysteresis, for example early examples of such papers are Hysteresis and periodic solutions of semilinear and quasilinear wave equations (1986) and Periodic solutions of partial differential equations with hysteresis (1986).
• He has also published an important book, Hysteresis, convexity and dissipation in hyperbolic equations (1996).
• Pavel Krejči's book Hysteresis convexity and dissipation in hyperbolic equations.

220. Valentina Mikhailovna Borok (1931-2004)
• Her undergraduate thesis on distribution theory and its applications to the theory of systems of linear partial differential equations was noted as outstanding and published in a top Russian journal.
• In 1954, Valentina graduated from Kiev University and moved (following G E Shilov) to the graduate school at Moscow State University, where she received a PhD in 1957 for a thesis On Systems of Linear Partial Differential Equations with Constant Coefficients.
• Her papers published in 1954-1959 contain a range of "inverse" theorems that allow partial differential equations to be characterized as parabolic or hyperbolic, by certain properties of their solutions.
• In the same period she obtained formulae that made it possible to compute in simple algebraic terms the numerical parameters that determine classes of uniqueness and well-posedness of the Cauchy problem for systems of linear partial differential equations with constant coefficients.
• In the early 1960s Valentina worked on fundamental solutions and stability for partial differential equations well-posed in the sense of Petrovskii.
• Starting in the late 1960s, Valentina began a series of papers that lay the foundations for the theory of local and non-local boundary value problems in infinite layers for systems of partial differential equations.
• In the early 1970s Valentina Borok founded a school on the general theory of partial differential equations in Kharkov.
• The work of Valentina Borok and her school on boundary value problems in layers forms an important chapter in the general theory of partial differential equations.
• Her other important contributions were in the area of difference, difference-differential, and functional-differential equations.
• She also developed and published original lecture notes on a number of other core, as well as more specialized courses, in analysis and partial differential equations.

221. Otakar Boruvka (1899-1995)
• He discussed these matters with Frantisek Vycichlo, a Prague mathematician, and their feeling was that differential equations would be a good direction to take his research team.
• Boruvka had already written a paper on differential equations in 1934, but now he began to direct the research of Masaryk University towards that topic.
• His own recollections about this period are given in [',' P Sarmanova, From the recollections of Otakar Boruvka - the founder of the Brno school of differential equations, Arch.
• We discussed the matter thoroughly and arrived at the conclusion that it was essential to start pursuing the theory of differential equations which is immensely important as far as applications are concerned and which was much neglected before the war and in essence it was not at all developed.
• In 1946 Boruvka became an ordinary professor at Masaryk University and in the following year he set up a Differential Equations Seminar.
• The main aim of the seminar was to study global properties of linear differential equations of the nth order.
• He explains [',' P Sarmanova, From the recollections of Otakar Boruvka - the founder of the Brno school of differential equations, Arch.
• Boruvka's publications on this topic include Sur les integrales oscilatoires des equations differentielles lineaires du second ordre Ⓣ (1953), Remark on the use of Weyr's theory of matrices for the integration of systems of linear differential equations with constant coefficients (Czech) (1954), Uber eine Verallgemeinerung der Eindeutigkeitssatze fur Integrale der Differentialgleichung y' = f (x, y) Ⓣ (1956), and Sur la transformation des integrales des equations differentielles lineaires ordinaires du second ordre Ⓣ (1956).
• Let us end this biography with Boruvka's own words about his approach to mathematics [',' P Sarmanova, From the recollections of Otakar Boruvka - the founder of the Brno school of differential equations, Arch.

222. Jean Leray (1906-1998)
• This led to a collaboration between Leray and Schauder and their joint work led to a paper Topologie et equations fonctionelles Ⓣ published in the Annales scientifiques de l'Ecole normale Superieure.
• This 1934 paper on topology and partial differential equations is of major importance:- .
• This degree is then used in an ingenious method to prove the existence of solutions to complicated partial differential equations.
• He then returned to work on analysis, in particular studying differential equations arising from hydrodynamics.
• He studied solutions of the initial value problem for three-dimensional Navier-Stokes equations.
• He studied time dependent hyperbolic partial differential equations and also began to work on the Cauchy problem.
• In particular he published a paper on the Cauchy problem for equations with variable coefficients in 1956.
• He was able to generalise results in the theory of ordinary linear analytic differential equations to obtain similar results for partial differential equations.
• In his hands, energy estimates for partial differential equations became combined with ideas from algebraic topology (such as fixed point theorems) in a highly original combination which cracked open the toughest problems.
• Mathematician of penetration and originality, whose inventions revolutionized partial differential equations and algebraic topology.

223. Mikio Sato (1928-)
• I then wanted to give some concrete example of it in the analysis of differential equations.
• Sato explained the new theory of microlocal analysis in his lecture Regularity of hyperfunctions solutions of partial differential equations at the International Congress of Mathematicians at Nice in 1970, but the details appear in the 165 page paper by Sato, Kawai and Kashiwara Microfunctions and pseudo-differential equations in the proceedings of the Katata Conference held in 1971.
• In this series we deal with these objects: (1) Deformation theory for linear differential equations (Riemann-Hilbert problem and its generalization to higher dimensions), (2) Quantum fields with critical strength (2-dimensional Ising model, etc.) and (3) Theory of Clifford group.
• A rich theory for differential equations has been the result.
• Hyperfunctions, together with integral Fourier operators, have become a major tool in linear partial differential equations.
• Sato provided a unified geometric description of soliton equations in the context of tau functions and infinitedimensional Grassmann manifolds.
• This was extended by his followers to other classes of equations, including self-dual Yang-Mills and Einstein equations.

224. Felix Browder (1927-2016)
• This area and partial differential equations have been my focus in the sixty years since, in particular nonlinear monotone operators from a Banach space to its dual.
• He published The Dirichlet problem for linear elliptic equations of arbitrary even order with variable coefficients and The Dirichlet and vibration problems for linear elliptic differential equations of arbitrary order in the Proceedings of the National Academy of Sciences in 1952, and further papers in the same Proceedings in the following year.
• He is in a field - a field of partial differential equations, which is a field in which the laws of radar, jet propulsion, atomic fission, all the basic laws of physics are expressed.
• The subject had its origins in the study of nonlinear ordinary and partial differential equations, but it came to encompass a wider range of questions in all branches of analysis and in differential geometry, in theoretical physics, and in economics.
• In the theory of linear elliptic partial differential equations, the work of Felix Browder and his school went well beyond the techniques first introduced by Russian analysts in establishing completeness theorems for the eigenfunctions of nonselfadjoint elliptic differential operators.
• This theorem led to the proof of some deep existence theorems for nonlinear partial differential equations and began a massive development of monotone operator methods and their applications to partial differential equations.
• He was their Colloquium Lecturer in 1973 giving the lectures Nonlinear functional analysis and its applications to nonlinear partial differential and integral equations.

225. Alexander Andreevich Samarskii (1919-2008)
• Andrei Nikolaevich Tikhonov was appointed as a professor at Moscow State University in 1936 following his defence of his habilitation thesis Functional equations of Volterra type and their applications to mathematical physics.
• The problem to be solved consisted of several hundred partial differential equations.
• He then divided up the problem in such a way that each of the girl computers had about 10 equations to solve and they had to pass their data to each other as they progressed the calculations.
• In 1951 Tikhonov and Samarskii published Equations of mathematical physics (Russian).
• Samarskii was the author of the principal results in the theory of differential equations with smooth and discontinuous coefficients and the theory of nonlinear equations; he posed and studied a number of nonclassical problems in mathematical physics.
• Of Samarskii's papers on mathematical physics and differential equations, we distinguish the brilliant work on nonclassical problems for partial differential equations and a large cycle of papers on the theory of nonlinear equations of mathematical physics that model peaking regimes.

226. Sergei Bernstein (1880-1968)
• Bernstein returned to Paris and submitted his doctoral dissertation Sur la nature analytique des solutions des equations aux derivees partielles du second ordre Ⓣ to the Sorbonne in the spring of 1904.
• This problem, posed by Hilbert at the International Congress of Mathematicians in Paris in 1900, was on analytic solutions of elliptic differential equations and asked for a proof that all solutions of regular analytical variational problems are analytic.
• In 1906 he passed his Master's examination at St Petersburg but only with difficulty since Aleksandr Nikolayevich Korkin, who examined him on differential equations, expected him to use classical methods of solution (some sources say that Bernstein only passed the examination at the second attempt).
• He moved to Kharkov in 1908 where he submitted a thesis Investigation and Solution of Elliptic Partial Differential Equations of Second Degree for yet another Master's degree.
• As well as describing his approach to solving Hilbert's 19th Problem, it also solved Hilbert's 20th Problem on the analytic solution of Dirichlet's problem for a wide class of non-linear elliptic equations.
• Mathematicians for a long time have confined themselves to the finite or algebraic integration of differential equations, but after the solution of many interesting problems the equations that can be solved by these methods have to all intents and purposes been exhausted, and one must either give up all further progress or abandon the formal point of view and start on a new analytic path.
• The analytic trend in the theory of differential equations has only recently become established; and only seven years ago the late Professor Korkin in a conversation with me spoke scornfully of the "decadence" of Poincare's work.
• As constructive function theory we want to call the direction of function theory which follows the aim to give the simplest and most pleasant basis for the quantitative investigation and calculation both of empirical and of all other functions occurring as solutions of naturally posed problems of mathematical analysis (for instance, as solutions of differential or functional equations).
• The theory of probability is indebted to S N Bernstein for fundamental contributions on a number of topics; the axiomatic theory of probability, the foundations of normal correlation using limit theorems and the development of the general theory of correlation, the extension of the central limit theorem to sums of stochastically dependent variables, especially to heterogeneous Markov chains, and stochastic differential equations; the application of the theory of probability to biology and economics and applications of the methods of the theory of probability to the constructive theory of functions.

227. Ludwig Sylow (1832-1918)
• Sylow continued his mathematical studies however (see [',' B Birkeland, Ludwig Sylow’s lectures on algebraic equations and substitutions, Christiania (Oslo), 1862: An introduction and a summary, Historia Mathematica 23 (2) (1996), 182-199.','5]):- .
• Finding Abel's papers on the solvability of algebraic equations by radicals more interesting, Sylow was led from them (by the professor in applied mathematics, Carl Bjerknes) to Galois.
• Although at first Sylow found reading Abel's papers a difficult task, soon he found that Abel had achieved a far deeper understanding of the theory of equations than his published papers indicated.
• made myself acquainted with newer works, particularly in the theory of equations.
• Bent Birkeland writes in [',' B Birkeland, Ludwig Sylow’s lectures on algebraic equations and substitutions, Christiania (Oslo), 1862: An introduction and a summary, Historia Mathematica 23 (2) (1996), 182-199.','5] that, as there were no courses being given in Berlin that interested him:- .
• he worked instead in the library, studying number theory and the theory of equations.
• It is interesting to note that no lectures in algebra or the theory of equations are mentioned from his stay either in Paris or in Berlin.
• In his lectures Sylow explained Abel's and Galois's work on algebraic equations.
• 15 (1) (1988), 40-52.','11] Winfried Scharlau describes how Sylow was led to his discovery by his study of Galois' work, in particular of Galois' criterion for the solvability of equations of prime degree.

228. Czesaw Olech (1931-2015)
• He defended his doctoral thesis On the asymptotic coincidence of sets filled up by integrals of two systems of ordinary differential equations on 26 April 1958.
• Ważewski had there presented his ideas of applying the topological notion of a retract to the study of the solutions of differential equations and Lefschetz had seen the idea as being one of the most significant advances in the study of differential equations.
• In particular he worked with Philip Hartman and they published the joint paper On global asymptotic stability of solutions of differential equations (1962).
• During Olech's year at Princeton, Lawrence Markus lectured on problems of global stability of differential equations and Olech was able to generalise some of the results.
• This thesis, On the global stability of an autonomous system on the plane, was published in the first volume of the journal Contributions to Differential Equations in 1963.
• The most important results in Professor Czeslaw Olech's scientific work have been in the qualitative theory of differential equations and in control theory.
• He obtained significant results for vector measures and their applications in the theory of differential equations and the theory of optimal control.
• He also solved very important problems concerning autonomous systems on the plane with stable Jacobian matrix at each point of the plane and applied the Ważewski topological method in studying the asymptotic behaviour of solutions of differential equations.

• Prthudakasvami is best known for his work on solving equations.
• The solution of a first-degree indeterminate equation by a method called kuttaka (or "pulveriser") was given by Aryabhata I.
• Brahmagupta seems to have used a method involving continued fractions to find integer solutions of an indeterminate equation of the type ax + c = by.
• In this commentary Prthudakasvami writes the equation 10x + 8 = x2 + 1 as: .
• The whole equation is therefore .

230. Siméon-Denis Poisson (1781-1840)
• In his final year of study he wrote a paper on the theory of equations and Bezout's theorem, and this was of such quality that he was allowed to graduate in 1800 without taking the final examination.
• During this period Poisson studied problems relating to ordinary differential equations and partial differential equations.
• Poisson's name is attached to a wide variety of ideas, for example:- Poisson's integral, Poisson's equation in potential theory, Poisson brackets in differential equations, Poisson's ratio in elasticity, and Poisson's constant in electricity.

231. Curtis McMullen (1958-)
• And I went to France and worked with Sullivan at Institut des Hautes Etudes Scientiques for a semester, and I met Steve Smale there who gave me this nice thesis problem on solving polynomial equations by iteration.
• Once a proper understanding was achieved of which polynomial equations could be solved by radicals, there remained the problem of finding the roots of a polynomial equation by an iterative procedure for those for which no formula existed.
• Newton had produced such a method and his iterative procedure generally converged for all quadratic polynomials and initial points, but this was not the case for polynomial equations of degree three.
• He has made important contributions to various branches of the theory of dynamical systems, such as the algorithmic study of polynomial equations, the study of the distribution of the points of a lattice of a Lie group, hyperbolic geometry, holomorphic dynamics and the renormalization of maps of the interval.

232. Max Mason (1877-1961)
• Mason's mathematical research interests lay in differential equations, the calculus of variations and electromagnetic theory.
• He developed the relation between the algebra of matrices and integral equations as well as studying boundary value problems.
• He published seven papers in the Transactions of the American Mathematical Society between 1904 and 1910: Green's theorem and Green's functions for certain systems of differential equations (1904), The doubly periodic solutions of Poisson's equation in two independent variables (1905), A problem of the calculus of variations in which the integrand is discontinuous (1906), On the boundary value problems of linear ordinary differential equations of second order (1906), The expansion of a function in terms of normal functions (1907); The properties of curves in space which minimize a definite integral (1908) and Fields of extremals in space (1910).

233. Irving Stringham (1847-1909)
• He delivered the lecture A Generalization, for n-fold Space, of Euler's Equation for Polyhedra on 21 January 1880.
• The main features of Schroder's system are, (1) its dualistic arrangement, by which to every addition equation a multiplication equation is made to correspond (and visa versa), (2) the transformation of every logical equation into a form in which the right hand member is zero, and (3) more especially his announcement of a Haupttheorem by means of which by a single operation two equations are obtained, from one of which any given class symbol is eliminated, while the other gives its value.

234. Louis Bachelier (1870-1946)
• ','4] on Brownian Motion, in which Einstein derived the equation (the partial differential heat/diffusion equation of Fourier) governing Brownian motion and made an estimate for the size of molecules, Bachelier had worked out, for his Thesis, the distribution function for what is now known as the Wiener stochastic process (the stochastic process that underlies Brownian Motion) linking it mathematically with the diffusion equation.
• In this course he may have drawn out the similarities between the diffusion of probability (the total probability of one being conserved) and the diffusion equation of Fourier (the total heat-energy being conserved).
• Bachelier's work is remarkable for herein lie the theory of Brownian Motion (one of the most important mathematical discoveries of the 20th century), the connection between random walks and diffusion, diffusion of probability, curves lacking tangents (non-differentiable functions), the distribution of the Wiener process and of the maximum value attained in a given time by a Wiener process, the reflection principle, the pricing of options including barrier options, the Chapman-Kolmogorov equations in the continuous case, .

235. Aleksandr Nikolaevich Korkin (1837-1908)
• He submitted On Determining Arbitrary Functions in Integrals of Linear Partial Differential Equations which he defended on 11 December 1860.
• On the Paris visit he was particularly interested in Bertrand's lectures on partial differential equations and in Germany Kummer's lectures on quadratic forms fascinated him.
• He defended his thesis On systems of first order partial differential equations and some questions on mechanics towards the end of 1867.
• One of Korkin's major contributions was to the development of partial differential equations.
• Initially Korkin was unimpressed with Zolotarev's investigation of an indeterminate equation of degree three which he presented in his Master' thesis.

236. Enrico Betti (1823-1892)
• The relative cultural insulation determined the original character of his research on the solution by radicals of algebraic equations.
• As Ulisse Dini notes in [',' U Dini, Enrico Betti, Annuario della R Universita di Pisa (1891-1892).','15], Betti worked in many, very different, mathematical areas such as: the theory of algebraic equations; the theory of elliptic functions, algebraic functions of a complex variable, on spaces of many dimensions etc in analysis and on the applications of this to geometry; he published many works on mathematical physics and celestial mechanics, the theory of Newtonian forces, the theory of heat, the theory of electricity, magnetism, elasticity, capillary, hydrodynamics, the motion of systems of particles, and the extension of the principles of dynamics.
• In his early work in the area of equations and algebra, as we have already seen, Betti extended and gave proofs relating to the algebraic concepts of Galois theory.
• In 1854 Betti showed that the quintic equation could be solved in terms of integrals resulting in elliptic functions.
• Although Jordan, in his Traite des substitutions et des equations algebriques Ⓣ (1870) credits Betti with having filled the gaps in Galois' arguments and with having been the first to establish the sequence of Galois' theorems rigorously, the fact is that Betti's work contains substantial obscurities and errors.

237. Heinrich Maschke (1853-1908)
• Maschke found working with Klein in his home in the evenings very rewarding and was fascinated with Klein's ideas on using group theory to solve algebraic equations.
• Hermite, Kronecker and Brioschi had, in 1858, discovered how to solve the quintic equation by means of elliptic functions.
• In 1888 Maschke proved that a particular sixth-degree equation could be solved by using hyperelliptic functions and Brioschi showed that any sixth-degree algebraic equation could be reduced to Maschke's equation and therefore solved in the same way.

• To Daniel Stroock and Srinivasa Varadhan for their four papers 'Diffusion processes with continuous coefficients I and II' (1969), 'On the support of diffusion processes with applications to the strong maximum principle (1970), Multidimensional diffusion processes (1979), in which they introduced the new concept of a martingale solution to a stochastic differential equation, enabling them to prove existence, uniqueness, and other important properties of solutions to equations which could not be treated before by purely analytic methods; their formulation has been widely used to prove convergence of various processes to diffusions.
• In his landmark paper 'Asymptotic probabilities and differential equations' in 1966 and his surprising solution of the polaron problem of Euclidean quantum field theory in 1969, Varadhan began to shape a general theory of large deviations that was much more than a quantitative improvement of convergence rates.
• Varadhan's book Lectures on diffusion problems and partial differential equations (1980) starts from Brownian motion and leads the students to stochastic differential equations and diffusion theory.

239. Leo Königsberger (1837-1921)
• Much of Konigsberger's work on differential equations was influenced by the function theory developed by his friend Fuchs.
• His work on differential equations was, however, also influenced by the applications which interested Bunsen, Kirchhoff and Helmholtz, with whom he was close friends in Heidelberg.
• His approach to the differential equations of analytic mechanics showed novelty [',' W Burau, Biography in Dictionary of Scientific Biography (New York 1970-1990).
• Konigsberger was the first to treat not merely one differential equation, but an entire system of such equations in complex variables.

240. Johann Friedrich Pfaff (1765-1825)
• It investigates the use of some functional equations in order to calculate the differentials of logarithmic and trigonometrical functions as well as the binomial expansion and Taylor formula.
• Pfaff did important work in analysis working on partial differential equations, special functions and the theory of series.
• In the 1815 paper, which Pfaff submitted to the Berlin Academy on 11 May, he presented a transformation of a first-order partial differential equation into a differential system.
• This theory of equations in total differentials is undoubtedly Pfaff's most significant contribution.
• constituted the starting point of a basic theory of integration of partial differential equations which, through the work of Jacobi, Lie, and others, has developed into a modern Cartan calculus of extreme differential forms.

241. Johann Hudde (1628-1704)
• Hudde worked on maxima and minima and the theory of equations.
• He gave an ingenious method to find multiple roots of an equation which is essentially the modern method of finding the highest common factor of a polynomial and its derivative.
• If in an equation two roots are equal and if it be multiplied by any arithmetical progression, i.e.
• the first term by the first term of the progression, the second by the second term of the progression, and so on: I say that the equation found by the sum of these products shall have a root in common with the original equation.

242. Anthony Spencer (1929-2008)
• A particular strain energy function (Neo-Hookean) is chosen, and the condition for existence of an adjacent equilibrium position is obtained in the form of a transcendental equation, which is solved numerically for two loading conditions.
• After introductory chapters on matrix algebra, vectors and Cartesian tensors, and an analysis of deformation and stress, the author examines the mathematical statements of the laws of conservation of mass, momentum and energy and the formulation of the mechanical constitutive equations for various classes of fluids and solids.
• A procedure has been developed in previous papers for constructing exact solutions of the equations of linear elasticity in a plate (not necessarily thin) of inhomogeneous isotropic linearly elastic material in which the elastic moduli depend in any specified manner on a coordinate normal to the plane of the plate.
• The essential idea is that any solution of the classical equations for a hypothetical thin plate or laminate (which are two-dimensional theories) generates, by straightforward substitutions, a solution of the three-dimensional elasticity equations for the inhomogeneous material.

243. Takakazu Seki (1642-1708)
• Ten years later Leibniz, independently, used determinants to solve simultaneous equations although Seki's version was the more general.
• He studied equations treating both positive and negative roots but had no concept of complex numbers.
• In 1685, he solved the cubic equation 30 + 14x - 5x2 - x3 = 0 using the same method as Horner a hundred years later.
• He discovered the Newton or Newton-Raphson method for solving equations and also had a version of the Newton interpolation formula.
• Among other problems studied by Seki were Diophantine equations.

244. Louis Arbogast (1759-1803)
• The particular mathematical dispute which prompted the question set by the St Petersburg Academy in 1787, however, concerned the arbitrary functions which appeared when a differential equation was integrated.
• d'Alembert claimed that these arbitrary functions were required to be continuous and must always be expressed in terms of algebraic or transcendental equations.
• Euler argued that more general functions could be introduced when differential equations were integrated.
• Do the arbitrary functions introduced when differential equations are integrated belong to any curves or surfaces either algebraic, transcendental, or mechanical, either discontinuous or produced by a simple movement of the hand? Or should they legitimately be applied only to continuous curves susceptible of being expressed by algebraic or transcendental equations? .

245. José Sebastiao e Silva (1914-1972)
• He published his first paper in Portugaliae Mathematica in 1940, this being On the numerical resolution of algebraic equations (Portuguese).
• In the following year he published Problems concerning rational functions of the roots of an algebraic equation (Portuguese) in the same journal.
• Determine the equation whose roots are all sums of p roots; if there is a factor in the field, then this equation has a root in the field.
• Assuming that it is possible to find all roots of an equation in a field, the preceding section furnishes a method of finding the coefficients of the factor, if it exists.

246. Alfred Dixon (1865-1936)
• Dixon's main area of research was in differential equations and he did early work on Fredholm integrals independently of Fredholm.
• He worked both on ordinary differential equations and on partial differential equations studying abelian integrals, automorphic functions, and functional equations.
• A spectacular generalisation of Dixon's beautiful identity is given by equation .31 on page 171 of [R L Graham, D E Knuth and O Patashnik, Concrete Mathematics (1989)] which must surely be the non plus ultra of the species.

247. Robert Carmichael (1879-1967)
• in 1911 for his thesis Linear Difference Equations and their Analytic Solutions Linear Difference Equations and their Analytic Solutions.
• by Indiana University for her thesis Transformations and Invariants Connected with Linear Homogeneous Difference Equations and Other Functional Equations in 1912.
• Show that if the equation φ(x) = n has one solution it always has a second solution, n being given and x being the unknown.

248. Beppo Levi (1875-1961)
• He had also studied the theory of integration, partial differential equations and the Dirichlet Principle, producing the famous "Beppo Levi theorem" and spaces now called "Beppo Levi spaces".
• He wrote articles on logic, differential equations, complex variable, as well as on the border between analysis and physics.
• He published Sistemas de ecuaciones analiticas en terminos finitos, diferenciales y en derivadas partiales (Systems of Analytic Equations: Equations in Finite Terms, Ordinary and Partial Differential Equations) (1944) as the first volume in the Monografias series.
• The problems related to the resolution of equations, whether finite or differential, assume fundamentally different aspects according to whether we postulate only the existence of such properties of continuity and differentiability of the given functions and the unknowns as are strictly necessary if a particular problem is to have meaning, or admit additional hypotheses relative to the existence of a certain number of successive derivatives, or finally grant at once the existence of all derivatives.
• This monograph is a clearly written exposition of the fundamental existence theorems for systems of analytic partial differential equations, together with necessary preliminary material on implicit functions and ordinary differential equations.

249. Vincenzo Riccati (1707-1775)
• Vincenzo continued his father's work on integration and differential equations but Giorgio Bagni notes differences in their approach in [',' G T Bagni, Differential equations in the works of Jacopo and Vincenzo Riccati (Italian), Riv.
• Vincenzo's favorite field of research is analysis, in particular setting out the analytical treatment of mechanical problems, conducted by solving differential equations, properly constructed.
• Vincenzo gave a collection of methods to solve certain specific types of differential equations in his memoir De usu motus tractorii in constructione Aequationum Differentialium Commentarius (1752).
• Here he notes new approaches by Euler and these influence him in finding a new method for solving differential equations.
• Vincenzo Riccati, somehow, put an end to this trend by showing that one could construct in a simple continuous way all transcendental curves from the differential equations that define them.
• It probably came too late, at the end of the period of construction of the curves, when geometry has given way to algebra, and when series became the tool of choice to represent the solutions of differential equations.
• Vincenzo studied hyperbolic functions and used them to obtain solutions of cubic equations.

250. Lars Hörmander (1931-2012)
• After Marcel Riesz retired in 1952 and went to the United States, Hormander began working on the theory of partial differential equations.
• Hormander spent the summers 1960-61 at Stanford University as an invited professor, and took advantage of this time to honour the offer of the 'Springer Grundlehren series' of publishing a book about partial differential equations.
• In Stockholm he had to set up a research group in partial differential equations.
• Since there was no activity in partial differential equations at Stockholm University at this time, he had to start from the beginning and lecture on distribution theory, Fourier analysis, and functional analysis.
• In August 1962 the International Congress of Mathematicians was held in Stockholm and Hormander, as well as being heavily involved in the organisation, received a Fields Medal for his work on partial differential equations.
• His impressive work on Partial Differential Equations, in particular his characterization of hypoellipticity for constant coefficients and his geometrical explanation of the Lewy non-solvability phenomenon were certainly very strong arguments for awarding him the Medal.
• Also his new point of view on Partial Differential Equations, which combined functional analysis with 'a priori' inequalities, had led to very general results on large classes of equations, which had been out of reach in the early fifties.

251. George Forsythe (1917-1972)
• The books he wrote were: Bibliography of Russian Mathematics Books (1956); (with Wolfgang Wasow) Finite-Difference Methods for Partial Differential Equations (1967); and (with Cleve B Moler) Computer Solution of Linear Algebraic Systems (1967).
• The author of [',' H P, Review: Finite-Difference Methods for Partial Differential Equations by George E Forsythe and Wolfgang R Wasow, Mathematics of Computation 16 (79) (1962), 379-380.','12] puts Finite-Difference Methods for Partial Differential Equations into context:- .
• The solution of partial differential equations by finite-difference methods constitutes one of the key areas in numerical analysis which have undergone rapid progress during the last decade.
• As a result, the numerical solution of many types of partial differential equations has been made feasible.
• The authors of this book have made an important contribution in this area, by assembling and presenting in one volume some of the best known techniques currently being used in the solution of partial differential equations by finite-difference methods.
• The book is also praised by George Leo Watson in [',' G L Watson, Review: Finite-Difference Methods for Partial Differential Equations by George E Forsythe and Wolfgang R Wasow, Biometrika 48 (3/4) (1961), 484.','15]:- .
• The aim of this monograph is to present, at the senior-graduate level, an up-to-date account of the methods presently in use for the solution of systems of linear equations.

252. Gene Golub (1932-2007)
• in 1959 for his thesis The Use of Chebyshev Matrix Polynomials in the Iterative Solution of Linear Equations Compared to the Method of Successive Overrelaxation which developed ideas in a paper by von Neumann.
• In 1992 Golub, jointly with James M Ortega, published Scientific computing and differential equations.
• A large part of scientific computing is concerned with the solution of differential equations, and thus differential equations are an appropriate focus for an introduction to scientific computing.
• The need to solve differential equations was one of the original and primary motivations for the development of both analog and digital computers, and the numerical solution of such problems still requires a substantial fraction of all available computing time.
• It is our goal in this book to introduce numerical methods for both ordinary and partial differential equations with concentration on ordinary differential equations, especially boundary value problems.
• Although there are many existing packages for such problems, or at least for the main subproblems such as the solution of linear systems of equations, we believe that it is important for users of such packages to understand the underlying principles of the numerical methods.

253. Maxime Bôcher (1867-1918)
• At Gottingen he also attended lecture courses by Klein on the potential function, on partial differential equations of mathematical physics and on non-euclidean geometry.
• Bocher published around 100 papers on differential equations, series, and algebra.
• Yet another exceptional service was rendered by his "Introduction to the Study of Integral Equations" ..
• Special attention should be drawn also to his little known pamphlet on regular point of linear differential equations of the second order used for a number of years in connection with one of his courses of lectures.
• When An introduction to the study of integral equations was reprinted in 1971 a reviewer wrote:- .
• His final book was Lecons sur les methodes de Sturm dans la theorie des equations differentielles lineaires et leurs developpements modernes (1917) which was a record of lectures he gave in Paris in 1913-14 when he was Harvard Exchange Professor at the University of Paris.
• He gave six lectures on Linear differential equations and their applications.
• He was honoured with election to the National Academy of Sciences (United States) in 1909 and he served as president of the American Mathematical Society during 1909-1910 delivering his presidential address in Chicago on The published and unpublished works of Charles Sturm on algebraic and differential equations.
• M Bocher: Integral equations .

254. Elizabeth Stephansen (1872-1961)
• During the time that she was teaching Stephansen was working on her doctoral dissertation on partial differential equations.
• Euler, d'Alembert and Lagrange had studied which second order partial differential equations which could be reduced to first order and this had been generalised by the Norwegian mathematician Alf Guldberg who, in 1900, had described all those third order partial differential equations which could be reduced to second order equations.
• In her thesis, Stephansen generalised Guldberg's work and succeeded in describing all those fourth order partial differential equations which could be reduced to equations of the third order.
• Stephansen published another paper in 1903 on differential equations, the idea for which came out of Hilbert's course of lectures that she attended.
• She continued to undertake mathematical research and wrote two further papers, this time on difference equations, which were published in 1905 and 1906.

255. Gabriele Manfredi (1681-1761)
• In the spring of 1706, Manfredi left Rome and returned to Bologna where he published his most famous work, De constructione aequationum differentialium primi gradus Ⓣ (Bologna 1707), the first monograph in the world dedicated to the study of differential equations [',' L Pepe, Gabriele Manfredi, in Dizionario Biografico degli Italiani 68 (2007).','4]:- .
• The work, in six sections, collected and presented in an orderly manner the results on first order differential equations scattered in the mathematical literature ..
• He first studied equations with algebraic solutions, then those that lead to transcendental curves, then moved on to equations that are solved by means of substitution of variables.
• The last section was a mixture of problems, some only proposed, such as integration of homogeneous equations.
• He continued to produce works on differential equations, publishing Breve schediasma geometrico per la costruzione di una gran parte delle equazioni di primo grado Ⓣ, in the Giornale de' letterati d'Italia in 1714.
• In this work he gave methods to integrate first order homogeneous differential equations.
• Most of these memoirs concern the integration of ordinary differential equations.

256. Rudolf Lipschitz (1832-1903)
• He carried out many important and fruitful investigations in number theory, in the theory of Bessel functions and of Fourier series, in ordinary and partial differential equations, and in analytical mechanics and potential theory.
• Lipschitz's work on the Hamilton-Jacobi method for integrating the equations of motion of a general dynamical system led to important applications in celestial mechanics.
• Lipschitz is remembered for the 'Lipschitz condition', an inequality that guarantees a unique solution to the differential equation y' = f (x, y).
• Peano gave an existence theorem for this differential equation, giving conditions which guarantee at least one solution.

257. Bevan Braithwaite Baker (1890-1963)
• Huygens' geometrical construction, with its restriction that only one sheet of the envelope of the spherical wavelets is to be considered, is first justified in Chapter I by Poisson's analytical solution of the equation of wave-motions.
• The analogue of Kirchhoff's formula, due to Volterra, is derived and an interesting account is given of a method, devised by Marcel Riesz and based on the theory of fractional integration, which provides a powerful method of solving initial value problems for equations like the wave equation.
• A second edition of the book, which differed from the first by the addition of a new chapter on the application of the theory of integral equations to problems of diffraction theory by a plane screen, was published in 1950.

258. Rufus Isaacs (1914-1981)
• In the Carrier Engineering Department, just after my engineering BS, there was a problem to be solved by a differential equation.
• Now, I had taken a course in differential equations; it told us how to set one up germane to a real-world problem and how to solve it; I was a master.
• Therefore, I wrote my equation including in it every detail of the problem.
• The course had given no hint that not all differential equations can be solved in elementary closed form.

259. Felix Klein (1849-1925)
• He owed some of his greatest successes to his development of Riemann's ideas and to the intimate alliance he forged between the later and the conception of invariant theory, of number theory and algebra, of group theory, and of multidimensional geometry and the theory of differential equations, especially in his own fields, elliptic modular functions and automorphic functions.
• He showed it had equation x3y + y3z + z3x = 0 as a curve in projective space and its group of symmetries was PSL(2,7) of order 168.
• Klein considered equations of degree greater than 4 and was particularly interested in using transcendental methods to solve the general equation of the fifth degree.

260. Robert Recorde (1510-1558)
• The book was the Second Part of Arithmetic, The Grounde of Artes being the first, covering the extraction of roots, the theory of equations and arithmetic with surds.
• In his study of quadratic equations, Recorde does not allow solutions which are negative, but he does allow negative coefficients.
• He makes good use of the sum and product of the roots stressing that for the equation .
• For many years Stifel was considered as Recorde's major source, but in [',' B Hughes, Robert Recorde and the first published equation, in Vestigia mathematica (Amsterdam, 1993), 163-171.','5] Hughes argues convincingly that Algebrae compendiosa by J Scheubel published in Paris in 1551 is Recorde's major source.

261. Pelageia Polubarinova Kochina (1899-1999)
• An application of the theory of linear differential equations to some problems of ground-water motion published in 1940 is quite typical of many of her papers.
• For example in 1948 she studied numerical solutions of a partial differential equation in On a nonlinear partial differential equation arising in the theory of filtration.
• The papers in this book are divided into eight sections: Kinematics of atmospheric motions; Hydrodynamics; Applications of the analytical theory of linear differential equations in filtration theory; Steady flow in the presence of porous media; Unsteady motion of groundwater; Problems on oil filtration; Gas filtration through coal layers; and Filtration of liquids through porous media.

262. Herbert Wilf (1931-2012)
• The title of the thesis was "The transmission of neutrons in multilayered slab geometry." It solved the transport equation in multilayered geometry by regarding each homogeneous layer as a little black box with prescribed inputs and outputs (which point of view was Jerry's hallmark), and it wired them together by representing each by a matrix.
• Even before the award of his doctorate, Wilf had written a remarkable range of papers: (with M Kalos) Monte Carlo solves reactor problems (1957); An open formula for the numerical integration of first order differential equations (1957); An open formula for the numerical integration of first order differential equations.
• After that normalization, the basic "WZ" equation F(n+1, k) - F(n, k) = G(n, k+1) - G(n, k) appeared in the room, and its self-dual symmetrical form was very compelling.

263. Calogero Vinti (1926-1997)
• He remained at Palermo undertaking research on partial differential equations and when Baiada returned from three years studying in the United States in 1952, the two began a close collaboration.
• The first of these papers gives an existence theorem for the equation zx = f (x, y, z, zy) using methods which had been developed by Baiada a couple of years earlier in solving a simpler equation.
• The scientific interests of Calogero Vinti covered several areas of Mathematical Analysis, from Calculus of Variations to Differential Equations, from Approximation Theory to Real Analysis and Measure Theory.

264. John Crank (1916-2006)
• His main work was on the numerical solution of partial differential equations and, in particular, the solution of heat-conduction problems.
• John Crank is best known for his joint work with Phyllis Nicolson on the heat equation, where a continuous solution u(x, t) is required which satisfies the second order partial differential equation .
• Crank and Nicolson's method, which is numerically stable, requires the solution of a very simple system of linear equations (a tridiagonal system) at each time level.

265. Ernesto Pascal (1865-1940)
• He developed the intergraph, an instrument for the mechanical integration of differential equations.
• A discussion is given of the theory of the integraph of Abdank-Abakanowicz with various improvements and modifications which the author has made in order to enable him to solve special types of first and second order differential equations, such as the general linear first order equation, the equation y" = (y3/x)1/2, etc.

266. Robert Woodward (1849-1924)
• However, he also published several papers in the Bulletin of the American Mathematical Society such as: On the cubic equation defining the Laplacian envelope of the earth's atmosphere (1897), On the integration of a system of simultaneous linear differential equations (1897), On the differential equation defining the Laplacian distribution of density, pressure, and acceleration of gravity in the earth (1898), On the mutual gravitational attraction of two bodies whose mass distributions are symmetrical with respect to the same axis (1898), and An elementary method of integrating certain linear differential equations (1900).

267. Joseph Boussinesq (1842-1929)
• In his first derivation of the solitary wave, published in 1871 in the 'Comptes rendus', Boussinesq sought an approximate solution of Euler's equations that propagated at the constant speed c without deformation in a rectangular channel.
• Lagrange had already tried this route and written the resulting series of differential equations, but had found their integration to exceed the possibilities of contemporary analysis unless nonlinear terms were dropped.
• Mecanique 335 (2007), 479-495.','6] Bois collects these under the following headings: The problem of static stresses in soils; Turbulent flows (first phase); Surface waves and Boussinesq's equation; The BBO equation and the 'historical term' of Basset-Boussinesq; and The method of potential, the 'Boussinesq problem' and the vibrations of bars.

268. Daniel Bernoulli (1700-1782)
• The third part of Mathematical exercises was on the Riccati differential equation while the final part was on a geometry question concerning figures bounded by two arcs of a circle.
• He was able to give the basic laws for the theory of gases and gave, although not in full detail, the equation of state discovered by Van der Waals a century later.
• Daniel worked on mechanics and again used the principle of conservation of energy which gave an integral of Newton's basic equations.
• It is especially unfortunate that he could not follow the rapid growth of mathematics that began with the introduction of partial differential equations into mathematical physics.

269. Richard Hamming (1915-1998)
• His doctoral dissertation Some Problems in the Boundary Value Theory of Linear Differential Equation was supervised by Waldemar Trjitzinsky (1901-1973).
• His interests were in analysis, particularly measure theory, integration and differential equations.
• Hamming did, however, develop interests in ideas that were quite far removed from his study of differential equations [',' R W Hamming, Mathematics on a Distant Planet, Amer.
• Hamming also worked on numerical analysis, integrating differential equations, and the Hamming spectral window which is much used in computation for smoothing data before Fourier analysing it.

270. Julius Petersen (1839-1910)
• The interest he had shown in ruler and compass constructions when he was at school had continued to influence his research topic and his doctoral thesis was entitled On equations which can be solved by square roots, with application to the solution of problems by ruler and compass.
• If the equation of degree 2n can be solved by square roots, one of the roots can be expressed by n such different square roots, where each can appear several times.
• His research was on a wide variety of topics from algebra and number theory to geometry, analysis, differential equations and mechanics.
• He published The theory of algebraic equations in 1877 which was written in a concise style, treating as many topics as possible without using Galois theory.

271. László Rédei (1900-1980)
• The paper [',' I-Kh I Gerasim, On the genesis of Redei’s theory of the equation x2 - Dy2 = -1 (Russian), Istor.-Mat.
• In 1953 L Redei published his famous article "Die 2-Ringklassen-gruppe des quadratischen Zahlkorpers und die Theorie des Pell-schen Gleichung" Ⓣ, after many years of investigation of Pell's equation.
• He gave a unified theory for the structure of class groups of real quadratic number fields and conditions for solvability of Pell's equation and other indeterminate equations.

272. Wolfgang Hahn (1911-1998)
• The direct method or, as Lyapunov called it in his memoir 'Probleme general de la stabilite du mouvement' Ⓣ (1947), the second method, embodies all those criteria for the stability and instability of a solution of an equation x' = f(t, x) that have one feature in common: they are based solely upon properties of scalar functions V(t, x) and their total derivative ∂V/∂t + grad V .
• f and do not depend upon considerations of variational equations and the like.
• There are also remarks on the practically important topic of finite time stability, extensions of the method to metric spaces and differential-difference and difference equations.
• The material of the 1959 book was considerably expanded and the basic concepts were introduced in a leading chapter on the stability problem for linear equations and the early stability criteria, algebraic and geometric, an approach which resulted in a methodologically and didactically well-balanced textbook.

273. William Feller (1906-1970)
• He transformed the relation between Markov processes and partial differential equations.
• Other papers written by Feller while still at Brown University include: On the time distribution of so-called random events (1940), On the integral equation of renewal theory (1941), On A C Aitken's method of interpolation (1943), The fundamental limit theorems in probability (1945) and Note on the law of large numbers and "fair" games (1945).
• outlines some new results and open problems concerning diffusion theory where we find an intimate interplay between differential equations and measure theory in function space.
• It was also the first mathematics course I took at Princeton (a course in sophomore differential equations).

274. Nikoloz Muskhelishvili (1891-1976)
• His next papers were On heat stresses in the plane problem of the theory of elasticity (Russian) (1916), On the definition of harmonic functions by means of data on a contour (Russian) (1917) and Sur l'integration de l'equation biharmonique Ⓣ (1917).
• He published Sur l'equilibre des corps elastiques soumis a l'action de la chaleur Ⓣ (1923), The solution of an integral equation encountered in the theory of black body radiation (Russian) (1924) and in 1925 he published, jointly with George Nikoladze and Archil Kirillovich Kharadze (1895-1976), a dictionary of Russian-Georgian, Georgian-Russian mathematical terms.
• A third area was on boundary problems for harmonic and biharmonic functions while a fourth was the study of singular integral equations and boundary problems for analytic functions [',' M L Williams, In memoriam Nikolai Ivanovich Muskhelishvili, Internat.
• The results obtained were applied to the theory of singular integral equations on broken contours .These results have important applications in technical and physical problems.
• His second well-known monograph 'Singular Integral Equations, Boundary-Value Problems in the Theory of Functions, and Some Applications to Mathematical Physics' (1946, 1962, 1968), went through three editions and was translated into English [(1953)].

• Arnold has also made innumerable and fundamental contributions to the theory of differential equations, symplectic geometry, real algebraic geometry, the calculus of variations, hydrodynamics, and magneto- hydrodynamics.
• The areas are Dynamical Systems, Differential Equations, Hydrodynamics, Magnetohydrodynamics, Classical and Celestial Mechanics, Geometry, Topology, Algebraic Geometry, Symplectic Geometry, and Singularity Theory.
• He published Problemes ergodiques de la mecanique classique Ⓣ (with A Avez) (1967), Ordinary differential equations (Russian) (1971), Mathematical methods of classical mechanics (Russian) (1974), Supplementary chapters to the theory of ordinary differential equations (Russian) (1978), Singularity theory (1981), Singularities of differentiable mappings (Russian) (with A N Varchenko and S M Gusein-Zade) (1982), Catastrophe theory (1984), Huygens and Barrow, Newton and Hooke (Russian) (1989), Contact geometry and wave propagation (1989), Singularities of caustics and wave fronts (1990), The theory of singularities and its applications (1991), Topological invariants of plane curves and caustics (1994), Lectures on partial differential equations (Russian) (1997), Topological methods in hydrodynamics (with B A Khesin) (1998), and Arnold problems (Russian) (2000).
• for his deep and influential work in a multitude of areas of mathematics, including dynamical systems, differential equations, and singularity theory.
• In classical hydrodynamics the basic equations of an ideal fluid were derived by Euler in 1757 and major steps towards understanding them were taken by Helmholtz in 1858, and Kelvin in 1869.

276. David Spence (1926-2003)
• Obtaining equations under special conditions, Spence found numerical results for lift, pitching moment, and jet shape, which he compared with experimental results obtained from a wind tunnel.
• By similarity considerations, the displacements are expressed in terms of the solution of a pair of nonlinear ordinary differential equations satisfying two-point boundary conditions.
• We consider boundary value problems for the biharmonic equation in the open rectangle x > 0, -1 < y < 1, with homogeneous boundary conditions on the free edges y = ±1, and data on the end x = 0 of a type arising both in elasticity and in Stokes flow of a viscous fluid, in which either two stresses or two displacements are prescribed.
• For such 'noncanonical' data, coefficients in the eigenfunction expansion can be found only from the solution of infinite sets of linear equations, for which a variety of methods of formulation have been proposed.

277. Siegfried Aronhold (1819-1884)
• Certain linear partial differential equations which he came across in his work are characteristic of invariant theory and are named after him.
• Aronhold established his theory in general and does not derive any specific equations.
• His efforts to obtain equations independent of substitution coefficients led to linear partial differential equations of the first order, which have linear coefficients.
• These equations, which are characteristic of the theory of invariants, are known as 'Aronhold's differential equations'.
• Aronhold explicitly established the required fourth degree equations and formulated a theorem on plane curves of the fourth order.

278. Rafael Bombelli (1526-1572)
• It is unclear exactly how Bombelli learnt of the leading mathematical works of the day, but of course he lived in the right part of Italy to be involved in the major events surrounding the solution of cubic and quartic equations.
• Scipione del Ferro, the first to solve the cubic equation was the professor at Bologna, Bombelli's home town, but del Ferro died the year that Bombelli was born.
• Some results from Bombelli's incomplete Book IV are also described in [',' G S Smirnova, Geometric solution of the cubic equations in Raffaele Bombelli’s ’Algebra’ (Russian), Istor.
• History Topics: Quadratic, cubic and quartic equations .

279. Nikolai Luzin (1883-1950)
• Many of these mathematicians turned to other topics such as topology, differential equations, and functions of a complex variable.
• In 1931 Luzin himself turned to a new area when he began to study differential equations and their application to geometry and to control theory.
• Finikov had derived differential equations that determine all principal on a given surface, and Byushgens had obtained differential equations that determine surfaces which have a given linear element and admit a bending on a principal base.
• However, the question of solubility of these equations, in general, remained unclear.
• no example was found in which the equations ..
• up to 1938, when Luzin, by means of a subtle analysis of these equations, established that the existence of a principal base is rather rare.

280. Lamberto Cesari (1910-1990)
• During this period he studied surfaces given by parametric equations, in particular the Lebesgue area of such a surface.
• Three years later, in 1959, Cesari published the monograph Asymptotic behavior and stability problems in ordinary differential equations.
• In fact much of this appears in his book Optimization - theory and applications: Problems with ordinary differential equations published in 1983.
• In the last twenty years, much of his attention was devoted to the study of questions arising in nonlinear analysis and its applications to differential equations.
• We promised to return to his book Optimization - theory and applications: Problems with ordinary differential equations published three years after he retired.
• J Warga writes in [',' J Warga, Review: Optimization - Theory and applications, Problems with ordinary differential equations by Lamberto Cesari, Bull.
• E O Roxin also reviewed the book writing in [',' E O Roxin, Review: Optimization - Theory and applications, Problems with ordinary differential equations by Lamberto Cesari, SIAM Review 26 (3) (1984), 441-443.','5]:- .

281. Guo Shoujing (1231-1316)
• We should now look at the rather remarkable work which Guo did on spherical trigonometry and solving equations.
• To solve this equation Guo used a numerical method similar to Horner's method.
• The equation has two real roots, the smaller being the solution to the problem while the other, being numerically larger than the length of the arc, was rightly discarded by Guo.
• Two of the coefficients of the equation, namely the constant term and the coefficient of x2, involve the length a of the arc, so require a value to be chosen for π.

282. Lionel Cooper (1915-1977)
• He then played a major role in the British mathematical scene serving on the Mathematics Panel of the University Grants Committee in 1971-75 and other committees, as well as organising a major conference on differential equations at Chelsea College.
• His research was on a wide range of different but related topics: operator theory, transform theory, thermodynamics, functional analysis and differential equations.
• Using the exact equations of elasticity, and a Fourier transform integrating technique, conclusions are obtained as to (1) the velocities of propagation which can be obtained and in particular their upper bounds; (2) the dispersive nature of the waves, both longitudinal and transverse; (3) the velocity at which elastic energy can be expected to be transported.
• Other papers in which deal with applications include The uniqueness of the solution of the equation of heat conduction (1950).

283. John Pell (1611-1685)
• Pell's equation y2 = ax2 + 1, where a is a non-square integer, was first studied by Brahmagupta and Bhaskara II.
• It is often said that Euler mistakenly attributed Brouncker's work on this equation to Pell.
• However the equation appears in a book by Rahn which was certainly written with Pell's help: some say entirely written by Pell.
• Perhaps Euler knew what he was doing in naming the equation.
• Pell's equation .
• History Topics: Pell's equation .
• Math Forum (Pell's equation) .

284. Nicholas Saunderson (1682-1739)
• The chapters on algebra introduce the idea of an equation and how real life problems can be reduced to equations.
• The reader is shown how to solve quadratic equations, there other topics such as magic squares are studied.
• The final book presents the solution of cubic and quartic equations.

285. Moshe Carmeli (1933-2007)
• Among his publications at this time are The motion of a particle of finite mass in an external gravitational field (1964), Has the geodesic postulate any significance for a finite mass? (1964), Semigenerally covariant equations of motion.
• Derivation (1965), Semigenerally covariant equations of motion.
• The significance of the "tail" and the relation to other equations of motion (1965), Motion of a charge in a gravitational field (1965), The equations of motion of slowly moving particles in the general theory of relativity (1965), and Equations of motion without infinite self-action terms in general relativity (1965).
• During his time in this post he published papers such as Group analysis of Maxwell's equations (1969), Infinite-dimensional representations of the Lorentz group (1970), and SL(2, C) symmetry of the gravitational field dynamical variables (1970).
• students, and E Leibowitz) Gauge fields : Classification and equations of motion (1989):- .

286. Carl Siegel (1896-1981)
• Approximation of algebraic numbers by rationals and applications thereof to Diophantine equations.
• These include his improvement of Thue's theorem, described above, given in his 1920 dissertation, and its application to certain polynomial Diophantine equations in two unknowns, proving an affine curve of genus at least 1 over a number field has only a finite number of integral points in 1929.
• He had earlier than this in 1922, written papers on the functional equation of Dedekind's zeta functions of algebraic number fields and in 1921/23 made contributions to additive questions such as Waring type problems for algebraic number fields.
• He examined Birkhoff's work on perturbation theory solutions for analytical Hamiltonian differential equations near an equilibrium point using formal power series.

287. Ludwig Schlesinger (1864-1933)
• He then studied mathematics and physics at the universities of Heidelberg and Berlin between 1896 and 1887, and he received a doctorate from the University of Berlin in 1887 for a thesis on differential equations entitled: Uber lineare homogene Differentialgleichungen vierter Ordnung, zwischen deren Integralen homogene Relationen hoheren als ersten Grades bestehen Ⓣ.
• In this paper Schlesinger formulated the problem of isomonodromy deformations for a certain matrix Fuchsian equation.
• Prove the existence of linear differential equations having a prescribed monodromic group.
• The paper introduces what today are known as the Schlesinger transformations and Schlesinger equations which have an important role in differential geometry.

288. Henri Garnir (1921-1985)
• In Sur la theorie de la lumiere de M L de Broglie Ⓣ (1945) he compared the approach by Kemmer to the theory of the meson to de Broglie's modifications of Maxwell's equations.
• His fields of research were broad, including algebra and mathematical analysis, in particular the very active field of functional analysis, and the still booming area of partial differential equations, especially boundary value problems.
• Another of his interests was in the theory of boundary value problems for partial differential equations.
• In particular, he studied Green's functions as solutions to boundary value problems for the wave and diffusion equations.
• In the later part of his career, Garnir became interested in the propagation of singularities of solutions of boundary value problems for evolution partial differential equations.
• In recent years the use of such tools as operators in Hilbert and Banach spaces, the theory of distributions and other methods of functional analysis has become commonplace in investigations of problems in partial differential equations.
• Thus from its very beginning it was a Centre of international cooperation in the broad realms of functional analysis and partial differential equations.

289. Lois Griffiths (1899-1981)
• She received the degree in 1927 after submitting her dissertation Certain quaternary quadratic forms and diophantine equations by generalized quaternion algebras.
• In 1945 Griffiths produced a typewritten set of notes Determinants and systems of linear equations.
• She expanded the notes into a book which was published by John Wiley and Sons as Introduction to the theory of equations in 1945.
• slowly through the proofs of the important general theorems in the elementary theory of algebraic equations.
• Thomas Arnold Brown in a review indicates the style of the book [',' T A Brown, Review: Introduction to the Theory of Equations by Lois Wilfred Griffiths, The Mathematical Gazette 33 (303) (1949), 57-58.','2]:- .
• III (1945); and A note on linear homogeneous Diophantine equations (1946).
• She attended the American Mathematical Society meeting in Chicago in April 1947 and delivered the lecture Linear homogeneous diophantine equations on the afternoon of Friday 26 April.

290. Claude-Louis Navier (1785-1836)
• Navier is remembered today, not as the famous builder of bridges for which he was known in his own day, but rather for the Navier-Stokes equations of fluid dynamics.
• He gave the well known Navier-Stokes equations for an incompressible fluid in 1821 while in 1822 he gave equations for viscous fluids.
• We should note, however, that Navier derived the Navier-Stokes equations despite not fully understanding the physics of the situation which he was modelling.
• He did not understand about shear stress in a fluid, but rather he based his work on modifying Euler's equations to take into account forces between the molecules in the fluid.
• The irony is that although Navier had no conception of shear stress and did not set out to obtain equations that would describe motion involving friction, he nevertheless arrived at the proper form for such equations.

291. Guido Stampacchia (1922-1978)
• For three years he produced outstanding examination results in a wide range of courses such as Tutorial Sessions in Analysis and in Geometry, Calculus of Variations, Theory of Functions, and Ordinary Differential Equations.
• His thesis was concerned with an adaptation of an approximation procedure for Volterra integral equations due to Tonelli to boundary value problems for systems of ordinary differential equations.
• From the time Stampacchia took up his appointment in Naples, his research output was impressive consisting mainly of papers on differential equations and the calculus of variations.
• The years that Stampacchia spent in Pisa and Naples characterize the formation of his personality as an analyst: he was a passionate specialist in calculus of variations and in the theory of partial differential equations, a practitioner and an inspirer of research works of considerable depth and originality of thought.
• His 326 page text Equations elliptiques du second ordre a coefficients discontinus was published in 1966, then in 1967 he was elected President of the Italian Mathematical Union (Unione Matematica Italiana).
• On the one hand, variational inequalities have stimulated new and deep results dealing with nonlinear partial differential equations.

292. Heinrich Hertz (1857-1894)
• There were several new factors in the equation which affected the issue such as, on the negative side, his unhappiness with the working environment of engineering firms, and on the positive side, his enjoyment of the mathematics he had learnt as part of his engineering studies.
• However, it may have been a wise decision to delay beginning the work as S D'Agostino [',' S D’Agostino, Hertz’s researches and their place in nineteenth century theoretical physics, Centaurus 36 (1) (1993), 46-82.','11] suggests that Hertz's derivation of Maxwell's equations in 1884 formed an important part of the structural background to his studies on the propagation of electric waves which he now carried out.
• He searched for a mechanical basis for electrodynamics starting from Maxwell's equations.
• Maxwell's theory is Maxwell's system of equations.

293. Eizens Leimanis (1905-1992)
• Immediately he was on his travels again, this time going to Paris where he spent a year at the Henri Poincare Institute undertaking research on differential equations and celestial mechanics.
• Leimanis continued to publish and, when he was approaching 80, the paper On integration of the differential equation of central motion appeared.
• Assuming that the force acting on a particle is of the form f(r)g(q), the theory of infinitesimal transformations is applied to determine the forms of f(r) and g(q) for which the differential equation of central motion is integrable by quadratures or reducible to a first-order differential equation.

294. Fabian Franklin (1853-1939)
• Whenever, therefore, the trilinear coordinates of a point are such as to make this function equal to zero, its bilinear coordinates are infinite; nor are they infinite under any other supposition: and hence the equation formed by putting this common denominator equal to zero is called the equation of the infinitely distant straight line.
• These expressions, too, have a common denominator of the first degree; but the equation obtained by putting this denominator equal to zero represents simply the origin of coordinates, a point of no geometrical importance.
• Franklin went on to publish many other papers, such as (with J J Sylvester) A Constructive Theory of Partitions, Arranged in Three Acts, an Interact and an Exodion (1882), (with P A MacMahon) Note on the Development of an Algebraic Fraction (1983/84), Proof of a Theorem of Tchebycheff's on Definite Integrals 91885), Two Proofs of Cauchy's Theorem (1887), Some Theorems Concerning the Centre of Gravity (1888), Note on the Double Periodicity of the Elliptic Functions (1889), Note on Induced Linear Substitutions (1894), and Note on Linear Differential Equations with Constant Coefficients (1897).

295. Gustav de Vries (1866-1934)
• Gustav de Vries's name is well known to mathematicians because of the work of his doctoral dissertation which contained the Korteweg-de Vries equation.
• On 1 December 1894 de Vries had an oral examination on his thesis Bijdrage tot de kennis der lange golven Ⓣ which contained the famous Korteweg-de Vries equation.
• They found explicit, closed-form, travelling-wave solutions to the Korteweg - de Vries equation that decay rapidly.
• However, both Korteweg and de Vries seem to have completely missed the fact that the equation, now called the Korteweg-de Vries equation, had already appeared in the work of Joseph Valentin Boussinesq.
• In fact the equation appears as a footnote in Boussinesq's 680-page treatise Essai sur la theorie des eaux courantes Ⓣ (1885), but this should not in any way diminish the importance of de Vries's contribution.
• to commemorate the centennial of the equation by and named after Korteweg and de Vries.

• There are problems on extracting square and cube roots, problems on finding the solution to quadratic equations, problems on finding the sum of an arithmetic progression, and on solving systems of linear equations.
• Zhang gives the solution by solving a quadratic equation, but his formulae are not particularly accurate.
• In Chapter 3 problems which involve solving systems of equations occur.

297. David Gilbarg (1918-2001)
• His was work there took him into new areas of mathematics and involved fluid dynamics and nonlinear partial differential equations.
• Except for a paper relating to his thesis which was published in the Duke Mathematical Journal in 1942, all his remaining mathematical publications were in the areas of fluid dynamics and nonlinear partial differential equations.
• For many mathematicians, Gilbarg is best known for his remarkable book Elliptic Partial Differential Equations of Second Order written in collaboration with Neil Trudinger and published in 1977.
• I could never have imagined forty years ago when my book with David Gilbarg on elliptic partial differential equations was first published that it would get such recognition.
• the systematic development of the general theory of second order quasilinear elliptic equations and of the linear theory required in the process.
• Aside from his fluid dynamics work, undoubtedly [Gilbarg's] best-known contribution to the mathematical literature is the monograph "Elliptic Partial Differential Equations of Second Order," co-authored with his former Stanford PhD student Neil S Trudinger.
• At the recent commemorative conference in the Stanford Mathematics Department, James Serrin described the Gilbarg-Trudinger text as being "on the bookshelf of everyone working in partial differential equations, a monumental work which is one of the great lasting achievements of analysis." .

298. Martin Davis (1928-)
• Devise a process according to which it can be determined by a finite number of operations whether a given polynomial equation with integer coefficients in any number of unknowns is solvable in rational integers.
• Does there exist an algorithm to determine whether a Diophantine equation has a solution in natural numbers? .
• During these years when Davis was moving around spending time at various institutions, he published a number of important papers such as Arithmetical problems and recursively enumerable predicates (1953), The definition of universal Turing machine (1957), (with Hilary Putnam) Reductions of Hilbert's tenth problem (1958) and (with Hilary Putnam and Julia Robinson) The decision problem for exponential diophantine equations (1961).
• is a completely self-contained exposition of the proof that there is no algorithm for determining whether an arbitrary Diophantine polynomial equation with integer coefficients has an integer solution.

299. David Hilbert (1862-1943)
• Hilbert's work in integral equations in about 1909 led directly to 20th-century research in functional analysis (the branch of mathematics in which functions are studied collectively).
• Making use of his results on integral equations, Hilbert contributed to the development of mathematical physics by his important memoirs on kinetic gas theory and the theory of radiations.
• Many have claimed that in 1915 Hilbert discovered the correct field equations for general relativity before Einstein but never claimed priority.
• In this paper the authors show convincingly that Hilbert submitted his article on 20 November 1915, five days before Einstein submitted his article containing the correct field equations.
• Einstein's article appeared on 2 December 1915 but the proofs of Hilbert's paper (dated 6 December 1915) do not contain the field equations.
• In the printed version of his paper, Hilbert added a reference to Einstein's conclusive paper and a concession to the latter's priority: "The differential equations of gravitation that result are, as it seems to me, in agreement with the magnificent theory of general relativity established by Einstein in his later papers".
• Hilbert contributed to many branches of mathematics, including invariants, algebraic number fields, functional analysis, integral equations, mathematical physics, and the calculus of variations.

300. Ernst Peschl (1906-1986)
• this work lies on the common boundary between differential geometry, function theory (of one and several variables) and partial differential equations.
• in the Schwarz lemma; the essence is the relation between the standard hyperbolic metric in the unit disc and the Beltrami equation, to which particular differential invariants are associated.
• This situation has been generalized to different types of metrics, to equations of higher order and to more than one variable.
• Partielle Differentialgleichungen erster Ordnung Ⓣ (1973) provides an elementary introduction to first order partial differential equations while Differential-geometrie (1973) provides a clear, elementary and concisely presented introduction to local differential geometry in Euclidean and Riemannian spaces.

301. Michael Atiyah (1929-2019)
• Subsequently (in collaboration with I M Singer) he established an important theorem dealing with the number of solutions of elliptic differential equations.
• Beyond these linear problems, gauge theories involved deep and interesting nonlinear differential equations.
• In particular, the Yang-Mills equations have turned out to be particularly fruitful for mathematicians.
• Atiyah's lecture covered the Poincare conjecture, the Hodge conjecture, quantum Yang-Mills theory and the Navier-Stokes equation.

302. Salvatore Pincherle (1853-1936)
• His research mainly concerned functional equations and functional analysis.
• From about 1890, Pincherle published several papers in which he used the axiomatic approach with differential and integral equations.
• even though he was the author of the article on functional equations and operators in the French version of the "Encyclopedie des mathematique pures et appliquees" (1912), in which he gave a very detailed historical account and referred to his own work, Pincherle's work itself did not have much influence.
• the 1888 paper (in Italian) of S Pincherle on the 'Generalized Hypergeometric Functions' led him to introduce the afterwards named Mellin-Barnes integral to represent the solution of a generalized hypergeometric differential equation investigated by Goursat in 1883.

303. Peter Henrici (1923-1987)
• His next contribution Bergmans Integraloperator erster Art und Riemannsche Funktion Ⓣ (1952) is an elegant study of the representation of solutions of an elliptic partial differential equation in terms of analytic functions.
• His first book Discrete variable methods in ordinary differential equations, published by John Wiley & Sons in 1962, quickly won international acclaim and became a classic standard text on the topic.
• This book contains a comprehensive and up-to-date treatment of methods for the numerical integration of ordinary differential equations, especially those associated with initial-value problems.
• There is no doubt that this book is a valuable contribution to numerical analysis, and it will certainly have an important influence on future developments in the numerical integration of ordinary differential equations.

304. Dmitrii Viktorovich Anosov (1936-2014)
• His work was supervised by Pontryagin and during this period Anosov published a number of papers including: On stability of equilibrium states of relay systems (Russian) (1959); Averaging in systems of ordinary differential equations with rapidly oscillating solutions (Russian) (1960); and Limit cycles of systems of differential equations with small parameters in the highest derivatives (Russian) (1960).
• Anosov defended his thesis on averaging in systems of ordinary differential equations at Moscow University in 1961.
• Hilbert's 21st problem (the Riemann-Hilbert problem) belongs to the theory of linear systems of ordinary differential equations in the complex domain: does there exist a Fuchsian system having these singularities and monodromy? Hilbert was convinced that such a system always exists.
• He continues to work (2009) at the Department of Differential Equations in the Steklov Mathematical Institute and at present he is Head of Department and serves on the Academic Council of the Institute.
• He is also Chairman of the Dissertation Council covering the areas of Differential equations, Mathematical physics, and Theoretical physics.
• He also has been involved with the International Congresses of Mathematicians in other capacities, being a member of the panel to decide the scientific programme in the section "Dynamical systems and differential equations" for three of the Congresses, and on two of these occasions he chaired the panel.

305. Lodovico Ferrari (1522-1565)
• Ferrari discovered the solution of the quartic equation in 1540 with a quite beautiful argument but it relied on the solution of cubic equations so could not be published before the solution of the cubic had been published.
• Ferrari clearly understood the cubic and quartic equations more thoroughly than his opponent who decided that he would leave Milan that very night and thus leave the contest unresolved, so victory went to Ferrari.
• History Topics: Quadratic, cubic and quartic equations .

306. Abraham Gelbart (1911-1994)
• derive the equation of the locus of its centre.
• The basic idea was to construct a theory similar to complex function theory for the solutions of a system of generalized Cauchy-Riemann equations arising in the mechanics of continua.
• They published two joint papers on S-monogenic functions, namely On a class of differential equations in mechanics of continua (1943) and On a class of functions defined by partial differential equations (1944).

307. Alan Day (1941-1990)
• Within nine months he had completed his Master's degree and submitted a Master's thesis On modular equational classes.
• Some of Day's early papers are: Injectives in non-distributive equational classes of lattices are trivial (1970), A note on the congruence extension property (1971), Injectivity in equational classes of algebras (1972), Splitting algebras and a weak notion of projectivity (1973), Filter monads, continuous lattices and closure systems (1975), and Splitting lattices generate all lattices (1975).
• I came to work in the morning, wrote the equations down, and tried to manipulate them.

308. Aleksandr Osipovich Gelfond (1906-1968)
• Gelfond developed basic techniques in the study of transcendental numbers, that is numbers that are not the solution of an algebraic equation with rational coefficients.
• He also contributed to the study of differential and integral equations and to the history of mathematics.
• This book is very much in the spirit of the modern Russian school concerned with the so-called constructive theory of functions, approximative methods for the solution of differential equations, and so forth.
• Also in 1952 Gelfond published the low level Solving equations in integers which was translated into English in 1960.

309. Issai Schur (1875-1941)
• Third, he handled algebraic equations, sometimes proceeding to the evaluation of roots, and sometimes treating the so-called equation without affect, that is, with symmetric Galois groups.
• He was also the first to give examples of equations with alternating Galois groups.
• Sixth, in integral equations; .

310. Anatolii Volodymyrovych Skorokhod (1930-2011)
• He was awarded his doctorate in 1962 for his thesis Stochastic differential equations and limit theorems for random processes.
• They have ranged over almost all the fundamental areas of these theories, and Skorokhod's contribution to the development of subjects such as limit theorems for random processes, stochastic differential equations, and probability distributions in infinite dimensional spaces can scarcely be exaggerated.
• The book is primarily devoted to the development of certain probabilistic methods in the field of stochastic differential equations and limit theorems for Markov processes.
• In [',' V S Korolyuk and N I Portenko, A V Skorokhod’s research in the area of limit theorems for random processes and the theory of stochastic differential equations (Russian), Ukrain.
• 42 (9) (1990), 1157-1170.','11] Korolyuk and Portenko survey Skorokhod's work on limit theorems for random processes, stochastic differential equations and the theory of Markov processes.
• Limit theorems for random processes and stochastic differential equations are the areas of probability theory in which, over 35 years ago, Skorokhod started his scientific career and contributed much to their far-reaching advances.
• III (1975), Controlled random processes (1977); and Stochastic differential equations and their applications (1982).

311. Alan Baker (1939-2018)
• This was awarded for his work on Diophantine equations.
• Perhaps the most significant of these impacts has been the application to Diophantine equations.
• It was Axel Thue who made the breakthrough to general results by proving in 1909 that all Diophantine equations of the form f (x, y) = m where m is an integer and f is an irreducible homogeneous binary form of degree at least three, with integer coefficients, have at most finitely many solutions in integers.
• Turan goes on to say that Carl Siegel and Klaus Roth generalised the classes of Diophantine equations for which these conclusions would hold and even bounded the number of solutions.
• He proved that for equations of the type f (x, y) = m described above there was a bound B which depended only on m and the integer coefficients of f with .
• Amongst the most significant are applications to the effective solution of Diophantine equations, to the resolution of class-number problems, to the theory of p-adic L-functions and especially, through works of Masser and Wustholz, to many deep aspects of arithmetical algebraic geometry.

312. Tullio Levi-Civita (1873-1941)
• the main mathematical and physical questions discussed by Einstein and Levi-Civita in their 1915 - 1917 correspondence: the variational formulation of the gravitational field equations and their covariance properties, and the definition of the gravitational energy and the existence of gravitational waves.
• Its major achievements are two: a derivation of the equations of motion of n point masses, free from the subtle errors besetting most of the standard treatments; and a careful discussion of the possible contributions, in the Einsteinian approximation, of the finite size and internal constitution of the bodies involved.
• He also wrote on the theory of systems of ordinary and partial differential equations.
• In [',' L Dell’Aglio and G Israel, The themes of stability and qualitative analysis in the works of Levi-Civita and Volterra (Italian), Italian mathematics between the two world wars (Pitagora, Bologna, 1987), 125-141.','18] the authors argue that Levi-Civita was interested in the theory of stability and qualitative analysis of ordinary differential equations for three reasons: his interest in geometry and geometric models; his interest in classical mechanics and celestial mechanics, in particular, the three-body problem; and his interest in stability of movement in the domain of analytic mechanics.
• Their results include the conception of the localized induction approximation for the induced velocity of thin vortex filaments, the derivation of the intrinsic equations of motion, the asymptotic potential theory applied to vortex tubes, the derivation of stationary solutions in the shape of helical vortices and loop-generated vortex configurations, and the stability analysis of circular vortex filaments.
• In 1933 Levi-Civita contributed to Dirac's equations of quantum theory.

313. Wolfgang Haack (1902-1994)
• However, around 1936, he began to work on problems in gas dynamics and differential equations, collaborating with his wife on these topics.
• As well as these books on geometry, he also continued his work on gas dynamics; for example in 1958 he published the paper (published jointly with his doctoral student Gerhard Bruhn) Ein Charakteristikenverfahren fur dreidimensionale instationare Gasstromungen Ⓣ in which he derived the characteristic equations for the unsteady three-dimensional motion of inviscid perfect gas.
• At the Technische Hochschule of Berlin, Haach lectured on systems of two linear partial differential equations of first order in two independent variables, in particular, elliptic systems.
• This book combines the study of partial and Pfaff differential equations.
• The point of view is to consider partial differential equations in the framework of Pfaff equations.

314. Sophus Lie (1842-1899)
• Although not on the permanent staff, Sylow taught a course, substituting for Broch, in which he explained Abel's and Galois' work on algebraic equations.
• Lie had started examining partial differential equations, hoping that he could find a theory which was analogous to the Galois theory of equations.
• the theory of differential equations is the most important discipline in modern mathematics.
• He examined his contact transformations considering how they affected a process due to Jacobi of generating further solutions of differential equations from a given one.
• It was during the winter of 1873-74 that Lie began to develop systematically what became his theory of continuous transformation groups, later called Lie groups leaving behind his original intention of examining partial differential equations.

315. William Brouncker (1620-1684)
• Brouncker gave a method of solving the diophantine equation .
• See our article Pell's equation for more details.
• It is believed that Euler made an error in naming the equation 'Pell's equation', and that he was intending to acknowledge the outstanding contribution made by Brouncker.
• It is interesting to think that if Euler had not made this error then Brouncker, instead of being relatively unknown as a mathematician, would be universally known through 'Brouncker's equation'.
• History Topics: Pell's equation .

316. Georges Lemaître (1894-1966)
• Einstein was at the conference and he spoke to Lemaitre in Brussels telling him that the ideas in his 1927 paper had been presented by Friedmann in 1922, but he also said that although he thought Lemaitre's solutions of the equations of general relativity were mathematically correct, they presented a solution which was not feasible physically.
• In 1942 he published L'iteration rationnelle Ⓣ in which he discussed Gauss's method of successive approximations applied to a system of two equations in two unknowns to determine the orbit of a planet from three observations.
• Lemaitre then applied these ideas to accelerate the orthodox process of iteration, taking the Picard iterative solution of first order differential equations as an example.
• He applied the same techniques in another paper published in the same year, namely Integration d'une equation differentielle par iteration rationnelle Ⓣ.
• In Sur un cas limite du probleme de Stormer Ⓣ (1945) he studied trajectories of an electron in the neighborhood of lines of force of a magnetic dipole field, then returned to his study of numerical solutions to first order differential equations in Interpolation dans la methode de Runge-Kutta Ⓣ (1947).
• Is it possible to account for the existence of more or less permanent concentrations of galaxies in which no single galaxy remains long in the same place? The two-fold purpose of the paper is to delineate the underlying mechanical model and to write down the fundamental equations of the problem.
• It is shown how these equations can be applied toward the solution of the well-known problem of uniform distribution in a homogeneous, expanding universe.

317. Gaetano Fichera (1922-1996)
• M Zerner, reviewing [',' A Cialdea and F Lanzara, Some contributions of G Fichera to the theory of partial differential equations, in Homage to Gaetano Fichera (Seconda Univ.
• Gaetano Fichera was at the heart of the important developments connecting physics (mostly elasticity), functional analysis and the theory of partial differential equations and inequalities which took place after WWII, many of them in Italy where the mathematical study of the mechanics of continuous media was a well-established tradition.
• In pure mathematics Gaetano Fichera achieved considerable results in the following fields: mixed boundary value problems of elliptic equations; generalized potential of a simple layer; second order elliptic-parabolic equations; well posed problems; weak solutions; semicontinuity of quasi-regular integrals of the calculus of variations; two-sided approximation of the eigenvalues of a certain type of positive operators and computation of their multiplicity; uniform approximation of a complex function f(z); extension and generalization of the theory for potentials of simple and double layer; specification of the necessary and sufficient conditions for the passage to the limit under integral sign for an arbitrary set; analytic functions of several complex variables; solution of the Dirichlet problem for a holomorphic function in a bounded domain with a connected boundary, without the strong conditions assumed by Francesco Severi in a former study; construction of a general abstract axiomatic theory of differential forms; convergence proof of an approximating method in numerical analysis and explicit bounds for the error.
• Throughout the book the author gives special attention to methods and results having applications in the theory of partial differential equations.
• This contrasts with much current work on differential equations where "error bounds" commonly involve unspecified constants.

• After writing this thesis on algebraic functions and equations, he then worked on space curves.
• Adolf Kneser's early work was on algebraic functions and equations.
• One of these areas is that of linear differential equations; in particular he worked on the Sturm-Liouville problem and integral equations in general.
• He wrote an important text on integral equations.
• the first to introduce Hilbert's new methods into analysis in his textbook on integral equations.

319. Franciszek Szafraniec (1940-)
• Ważewski had built an important seminar at the Jagiellonian University which was mainly devoted to the study of differential equations.
• He was famed for his topological approach to the study of differential equations, and had obtained remarkable results applying Borsuk's theory of retracts.
• He was awarded a Master's degree (equivalent to a Ph.D.) in 1968 for a thesis on the theory of differential equations.
• The papers he wrote while he was undertaking research included: On a certain sequence of ordinary differential equations (1963); (with Andrzej Lasota) Sur les solutions periodiques d'une equation differentielle ordinaire d'ordre n Ⓣ (1966) and (with Andrzej Lasota) Application of the differential equations with distributional coefficients to the optimal control theory (1968).
• At the 1997 workshop 'Special functions and differential equations' held at Madras in India, he gave the talk The quantum harmonic oscillator in L2(R) in which he introduced the Hilbert-space model of the quantum harmonic oscillator couple of the creation and annihilation operators, he obtained some new interrelations between these operators.

320. Eberhard Hopf (1902-1983)
• Another important contribution from this period was the Wiener-Hopf equations, which he developed in collaboration with Norbert Wiener from the Massachusetts Institute of Technology.
• By 1960, a discrete version of these equations was being extensively used in electrical engineering and geophysics, their use continuing until the present day.
• Other work which he undertook during this period was on stellar atmospheres and on elliptic partial differential equations.
• An example of this was the dropping of Hopf's name from the discrete version of the so called Wiener-Hopf equations, which are currently referred to as "Wiener filter".
• His interests and principal achievements were in the fields of partial and ordinary differential equations, calculus of variations, ergodic theory, topological dynamics, integral equations, differential geometry, complex function theory and functional analysis.

321. Vyacheslaw Vassilievich Stepanov (1889-1950)
• He returned to Moscow in 1915 and, much influenced by Egorov and Luzin, he worked on periodic functions and differential equations.
• In the qualitative theory of differential equations he worked on the general theory of dynamical systems studied by G D Birkhoff.
• Besides writing articles on the study of almost periodic trajectories and on a generalisation of Birkhoff's ergodic theorem (which found an important application in statistical physics), Stepanov organised a seminar on the qualitative methods of the theory of differential equations (1932) that proved of great importance for the creation of the Soviet scientific school in this field.
• A graduate-level text Qualitative Theory of Differential Equations by Stepanov and his student Viktor V Nemytskii became a classic, the 1960 edition being reprinted in 1989.
• It considers existence and continuity theorems, integral curves of a system of two differential equations, systems of n-differential equations, general theory of dynamical systems, systems with an integral invariant, and many related topics.

322. Andrei Andreevich Bolibrukh (1950-2003)
• This was a useful activity connected with the applied orientation of the Moscow Institute of Physics and Technology and requiring a certain qualification, but it had nothing to do with linear differential equations in the complex domain.
• Does there exist a Fuchsian system of linear ordinary differential equations in the complex domain having prescribed singularities and monodromy group? .
• He was an invited lecturer at the International Congress of Mathematicians held in Zurich in 1994 giving the lecture The Riemann-Hilbert problem and Fuchsian differential equations on the Riemann sphere.
• In those years he gave the specialized lecture course on the analytic theory of differential equations, vector bundles and the Riemann-Hilbert problem.
• He prepared his lectures thoroughly, and one of his courses was published as the book Fuchsian differential equations and holomorphic bundles, which is a good example of his style.
• He agreed, and we joined the group working on differential equations, and later, together with him, joined the newly formed dynamical systems group.

323. Bernard Malgrange (1928-)
• Malgrange was awarded his doctorate in 1955 from the Universite Henri Poincare at Nancy for his thesis Existence et approximation des solutions des equations aux derivees partielles et des equations de convolution Ⓣ.
• These were the two-part paper Equations aux derivees partielles a coeficients constants Ⓣ (1953, 1954), and the papers Sur quelque proprietes des equations de convolution Ⓣ (1954) and Formes harmonique sur un espace de Riemann a ds2 analytique 2-analytic',1313)">Ⓣ (1955).
• We have mentioned his important work on linear partial differential equations above, but he has made numerous other very significant contributions to differential geometry, non-linear differential equations, and singularities of functions and mappings.
• In particular, he has studied hypoelliptic operators, ideals of differentiable functions, the classification of differential equations with regular singular points, and the algebraic theory of partial differential equations with variable coefficients.
• In 1991 Malgrange published Equations differentielles a coefficients polynomiaux Ⓣ.
• The modern algebraic theory of differential systems, or "theory of D-modules'', brings us new relations between two mathematical areas traditionally far apart: the theory of systems of linear partial differential equations and algebraic geometry.
• This book documents the development of the theory of linear differential equations with irregular singularities in the interaction between Deligne, Malgrange and Ramis.

324. Frederick Atkinson (1916-2002)
• A new phase of his work began when he began to study eigenfunction expansions both for difference equations and differential equations.
• We shall present the theory of certain recurrence relations in the spirit of the theory of boundary problems for differential equations.
• Second, we shall present the theory of boundary problems for certain ordinary differential equations, emphasizing cases in which the coefficients may be discontinuous, or may have singularities of delta function type.
• Finally, we give some account of theories which unify the topics of differential and difference equations, relying mainly on the method of replacement by integral equations.

325. Renato Caccioppoli (1904-1959)
• After 1930 Caccioppoli devoted himself to the study of differential equations and he provided existence theorems for both linear and non-linear problems.
• His idea was to use a topological- functional approach to the study of differential equations.
• Carrying on in this way Caccioppoli, in 1931, extended in some cases Brouwer's fixed point theorem, and applied his results to existence problems of both partial differential equations and ordinary differential equations.
• In the period between 1933 and 1938 Caccioppoli applied his method to elliptic equations, providing the a priori upper bound for their solutions, in a more general way than Bernstein did for the two-dimensional case.
• In 1935 he dealt with the question introduced in 1900 by Hilbert during the International Congress of Mathematicians, namely whether or not the solutions of analytical elliptic equations are analytic.

326. Vera Nikolaevna Kublanovskaya (1920-2012)
• Using analytical computational devices, this group was solving systems of linear algebraic equations.
• the method is applied to particular problems such as, for instance, solution of systems of linear equations, determination of eigenvalues and eigenvectors of a matrix, integration of differential equations by series, solution of Dirichlet problem by finite differences, solution of integral equations, etc.
• The paper is concerned with finding, without the use of the Gaussian transformation, the normal generalized (in the sense of the least-squares method) solution for a system of linear algebraic equations with a rectangular matrix.
• We have only been able to give a brief indication of the many papers which she had published - MathSciNet lists 134 publications in the areas of Commutative rings and algebras, Functions of a complex variable, History and biography, Linear and multilinear algebra, Numerical analysis, Ordinary differential equations and Systems theory.

327. Jack Warga (1922-2011)
• He wrote a book which has become a classic, namely Optimal Control of Differential and Functional Equations (1972).
• Lamberto Cesari writes [',' L Cesari, Review: Optimal Control of Differential and Functional Equations, by J Warga, SIAM Review 17 (3) (1975), 579-580.','1]:- .
• Along with the unilateral constraints on the state variable, the side conditions extensively investigated in the book are ordinary differential equations with or without delays, functional integral equations and functional equations in general Banach spaces.
• Several weeks later however, I received a phone call from Jack asking me to help him find two articles on differential equations.

328. Nikolai Nikolaevich Krasovskii (1924-2012)
• Barbashin organized a seminar on qualitative methods in the theory of differential equations gathering round him an excellent team working on mathematics and mechanics.
• Barbashin influenced Krasovskii to work on the stability theory of motion and Krasovskii published his first papers Theorems on the stability of motions governed by a system of two equations and (with Evgenii Alekseevich Barbashin) The stability of motion as a whole in 1952.
• Applications of Lyapunov's second method to differential systems and equations with delay and published in 1963.
• At the Gorkii Ural State University he set up a school of control theory and differential equations.
• The author is himself a distinguished contributor to the theory of optimal control on the basis of his previous valuable results in the qualitative theory of differential equations and Lyapunov stability theory.
• The problems are formulated in terms of linear and quasilinear ordinary differential equations.

329. Alessandro Faedo (1913-2001)
• He worked tirelessly to make the Scuola Normale a world leading centre for mathematics [',' M Benzi and E Toscano, Mauro Picone, Sandro Faedo, and the Numerical Solution of Partial Differential Equations in Italy (1928-1953), Department of Mathematics and Computer Science, Emory University, Atlanta, Georgia.','5]:- .
• We have already seen that he made contributions to a wide variety of areas such as the calculus of variations, the theory of linear ordinary differential equations, the theory of partial differential equations, measure theory, the Laplace transform for functions of several variables, questions relating to existence for linear equations in Banach spaces, and foundational problems such as his work on Zermelo's principle in infinite-dimensional function spaces.
• This paper contains a description and analysis of a method for solving time-dependent partial differential equations which is today known as the Faedo-Galerkin method [',' M Benzi and E Toscano, Mauro Picone, Sandro Faedo, and the Numerical Solution of Partial Differential Equations in Italy (1928-1953), Department of Mathematics and Computer Science, Emory University, Atlanta, Georgia.','5]:- .

330. Lester R Ford (1886-1967)
• Ford read the paper On the Roots of a Derivative of a Rational Function to the meeting of the Society on Friday 14 May 1915, the paper On the Oscillation Functions derived from a Discontinuous Function to the meeting on 11 June 1915, and the paper A method of solving algebraic equations to the meeting on 12 January 1917.
• Following his contributions to the war effort, Ford joined the faculty at the Rice Institution, Houston, Texas and while there he published papers such as On the closeness of approach of complex rational fractions to a complex irrational number (1925), The Solution of Equations by the Method of Successive Approximations (1925), On motions which satisfy Kepler's first and second laws (1927/28), and The limit points of a group (1929).
• Two significant books published by Ford are Automorphic Functions (1929) and Differential Equations (1933, second edition 1955).
• See reviews at THIS LINK for Differential Equations and THIS LINK for Automorphic Functions.
• Some of the papers are related to the fields of Ford's major interests: complex functions, interpolation, differential equations, and numerical analysis.
• L R Ford - Differential Equations .

331. Matyá Lerch (1860-1922)
• He attended courses on the theory of elliptic functions by Weierstrass, and courses on the theory of algebraic equations and on simple and multiple integrals by Kronecker.
• He also attended several lecture courses by Fuchs, namely (i) Introduction to the theory of infinite series, (ii) Integration of differential equations, (iii) The theory of linear differential equations, and (iv) Invariant theory.
• He also took Runge's courses on the solution of equations, on convergence and continuity, and on the differentiation of analytic expressions.
• He also studied elliptic functions and integral equations.
• He is remembered today for his solution of integral equations in operator calculus and for the 'Lerch formula' for the derivative of Kummer's trigonometric expansion for log G(v).

332. Leopold Infeld (1898-1968)
• During this time he wrote six joint papers with Max Born - examples of their papers in the Proceedings of the Royal Society are Foundations of the new Field Theory (1934) and On the Quantization of the New Field Equations (1935).
• For example he published (jointly with A Einstein and B Hoffmann) The gravitational equations and the problem of motion (1938) and a second part, jointly with Einstein, two years later.
• the gravitational field equations, satisfied in regions free of matter, imply the vanishing of certain surface integrals taken over 2-dimensional surfaces enclosing spatial regions containing the particles responsible for the field.
• In obtaining this result the authors made use of a normalizing condition restricting the choice of coordinates; with it they were able to show that the vanishing of the surface integrals led to equations of motion for the particles.
• Other papers he published around this time include (with P R Wallace, one of his doctoral students) The equations of motion in electrodynamics (1940), On the Theory of Brownian Motion (1940), On a new treatment of some eigenvalue problems (1941), A generalization of the factorization method for solving eigenvalue problems (1942), and Clocks, rigid rods and relativity theory (1943).
• The problem is a substantial one, because the field equations are non-linear, and because they are connected by differential identities.

333. George-Henri Halphen (1844-1889)
• He was led to extend results due to Max Noether which, in turn, had him examine projective transformations which fix certain differential equations.
• A characterisation of such invariant differential equations appeared in Halphen's doctoral dissertation On differential invariants which he presented in 1878.
• Halphen made major contributions to linear differential equations and algebraic space curves.
• He examined problems in the areas of systems of lines, classification of space curves, enumerative geometry of plane conics, singular points of plane curves, projective geometry and differential equations, elliptic functions, and assorted questions in analysis.
• For example, in 1880 he won the Grand Prix of the Academie des Sciences for his work on linear differential equations.
• Other work such as that on linear differential equations was overtaken by Lie group methods.

334. Hanno Rund (1925-1993)
• The importance of the Hamilton-Jacobi theory is stressed from the start, and so the pure mathematician gains immediate access to the theory of first-order partial differential equations, to that of some second-order partial differential equations, and to metric geometries.
• The theoretical physicist is shown how the theory of non-homogeneous single integral problems give rise to relativistic particle mechanics, in which the special invariant Hamiltonian function permits a particularly simple method of quantization, from which the relativistic wave equations (Dirac, Kemmer, etc.) may be obtained directly.
• This book is concerned with problems in the Calculus of Variations, with particular emphasis on the use of Hamilton's equations and of the Hamilton-Jacobi theorem.
• The approach is not that of the familiar derivation of Hamilton's equations from the Euler-Lagrange equations, but is based on Caratheodory's notion of the "complete figure".

335. Ellis Kolchin (1916-1991)
• Other papers around this time were Algebraic matric groups (1946) and The Picard-Vessiot theory of homogeneous linear ordinary differential equations (1946).
• His deep and abiding interest has always been in the application of the powerful and clarifying techniques of algebra to problems in the theory of differential equations.
• Following the tradition set by Joseph Fels Ritt (1893 - 1951), the founding father of differential algebra, his desire has been to remove the algebraic aspects of differential equations from analysis.
• It is intended that such a theory bear to algebraic groups the same relation that the theory of differential equations bears to the theory of algebraic equations.
• Algebraic groups can be viewed as groups in the category of algebraic varieties, where the latter are taken to be locally given as sets of simultaneous solutions of algebraic equations.

336. Evgenii Yakovlevich Khruslov (1937-)
• In 1965 Khruslov was awarded a Candidate's Degree for the innovative work on differential equations in his thesis Dirichlet boundary value problems in domains with fine-grained boundary for self-adjoint elliptic operators.
• So the question of how and under what conditions one can reduce problems of this type to significantly simpler problems for a homogeneous medium and find equations describing them is of great importance.
• In 2005 the same two authors published Homogenization of partial differential equations (Russian).
• The authors of this book are among the pioneers in homogenization theory: they considered differential equations in perforated domains in the early 1960s and their monograph 'Boundary value problems in domains with a fine-grained boundary' (Russian) was the first integral text on the subject.
• We consider a boundary value problem for a system of Navier-Stokes equations describing the flow of a viscous incompressible fluid around a large number of small particles with random distribution of their coordinates and velocities.
• We obtain equations describing the 'averaged' motion of a perturbed fluid.

337. Edward Van Vleck (1863-1943)
• Almost all Van Vleck's research papers were in the fields of function theory and differential equations.
• For example he published On the determination of a series of Sturm's functions by the calculation of a single determinant (1899), On linear criteria for the determination of the radius of convergence of a power series (1900), On the convergence of continued fractions with complex elements (1901), A determination of the number of real and imaginary roots of the hypergeometric series (1902), On an extension of the 1894 memoir of Stieltjes (1903), and On the extension of a theorem of Poincare for difference-equations (1912).
• Of the American Mathematical Society sometime president, and editor of the Transactions; always wise counsellor and leader; creative mathematician and successful investigator in the theory of functions, and in the theories of differential and difference equations and of functional equations; for these eminent services in mathematics, and especially for your important researches concerning functional equations and analytic continued fractions.

338. André Lichnerowicz (1915-1998)
• His thesis was published under this title, and also under the title Sur certains problemes globaux relatifs au systeme des equations d'Einstein Ⓣ.
• Chapter I (Axiomatique de la theorie de la gravitation Ⓣ) [gives] relevant results on the initial value problem associated with the field equations of general relativity; most important for the sequel are those which deal with the continuation of an "interior field," in a region containing matter, across a boundary into an "exterior field" in regions free of matter.
• The first part treats linear equations, determinants and matrices, Hermitian forms, characteristic roots and resolvents, and tensor algebra.
• The second surveys the theory of exterior differential forms, the general form of Stokes's theorem and its specialization to two and three dimensions, orthogonal series, Fourier integrals, bounded linear operators in Hilbert space, and the classical theory of integral equations for L2 integrable kernels.
• except during his lectures when he would fill the blackboard with equations in his dense handwriting, equations almost always comprising many tensorial indices.

339. Mark Aleksandrovich Krasnosel'skii (1920-1997)
• For example Positive solutions of operator equations (1962) which studied the existence, uniqueness, and properties of positive solutions of linear and non-linear equations in a partially ordered Banach space, Vector fields in the plane (1963) which the angular variation of a plane vector field relative to a curve, and Displacement operators along trajectories of differential equations (1966) which is described by C Olech as follows:- .
• For example Approximate solution of operator equations (1969):- .
• is devoted to the investigation of approximate methods of solving operator equations.

340. Petre Sergescu (1893-1954)
• There he was attended lectures by Gheorghe Țițeica, Dimitrie Pompeiu, Anton Davidoglu (1876-1958) an expert on differential equations, Traian Lalescu (1882-1929) who contributed to many areas particularly integral equations, Nicolae Coculescu (1866-1952) the professor of astronomy and celestial mechanics, and David Emmanuel (1854-1941) the professor of Higher Algebra and Function Theory.
• During this period he taught courses on Algebra, Integral Equations, Number Theory, Function Theory, and the History of Mathematics.
• For a while, in addition to history papers, he continued to publish papers on the roots of equations, a topic that he had been interested in for several years.
• For example he published On the roots of equations in which the coefficient of xp has the highest absolute value (Romanian) (1935).

341. Julius Schauder (1899-1943)
• While Schauder was in Paris he collaborated with J Leray and their joint work led to a paper Topologie et equations fonctionelles Ⓣ published in the Annales scientifiques de l'Ecole Normale Superieure.
• This 1934 paper on topology and partial differential equations is of major importance [',' W Forster, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1]:- .
• This degree is then used in an ingenious method to prove the existence of solutions to complicated partial differential equations.
• His last work was to generalise results of Courant, Friedrichs and Lewy on hyperbolic partial differential equations.
• In particular, Schauder's formulation of a fixed point theorem originated a new, extremely fruitful method in the theory of differential equations, known as Schauder's method ..
• Schauder's fixed point theorem and his skillful use of function space techniques to analyse elliptic and hyperbolic partial differential equations are contributions of lasting quality.

342. Jean Claude Saint-Venant (1797-1886)
• Perhaps his most remarkable work was that which he published in 1843 in which he gave the correct derivation of the Navier-Stokes equations.
• Seven years after Navier's death, Saint-Venant re-derived Navier's equations for a viscous flow, considering the internal viscous stresses, and eschewing completely Navier's molecular approach.
• Why his name never became associated with those equations is a mystery.
• We should remark that Stokes, like Saint-Venant, correctly derived the Navier-Stokes equations but he published the results two years after Saint-Venant.
• In 1871 he derived the equations for non-steady flow in open channels.

• In Book 2 of al-Bahir al-Samawal describes the theory of quadratic equations but, rather surprisingly, he gave geometric solutions to these equations despite algebraic methods having been fully described by al-Khwarizmi, al-Karaji, and others.
• Al-Samawal also described the solution of indeterminate equations such as finding x so that a xn is a square, and finding x so that axn + bxn-1 is a square.
• The final book of al-Bahir contains an interesting example of a problem in combinatorics, namely to find ten unknowns given the 210 equations which give their sums taken 6 at a time.
• Of course such a system of 210 equations need not be consistent and al-Samawal gave the 504 conditions which are necessary for the system to be consistent.

344. Alberto Calderón (1920-1998)
• Calderon, on the other hand, with his background as an engineer, saw that such operators held an important key to understanding the theory of partial differential equations.
• In 1958 Calderon published one of his most important results on uniqueness in the Cauchy problem for partial differential equations.
• for his ground-breaking work on singular integral operators leading to their application to important problems in partial differential equations, including his proof of uniqueness in the Cauchy problem, the Atiyah-Singer index theorem, and the propagation of singularities in nonlinear equations..
• Calderon's techniques have been absorbed as standard tools of harmonic analysis and are now propagating into nonlinear analysis, partial differential equations, complex analysis, and even signal processing and numerical analysis.

345. Anders Lexell (1740-1784)
• Lexell made a detailed investigation of exact equations differential equations.
• In addition Lexell developed a theory of integrating factors for differential equations at the same time as Euler but, although it has often been thought that he learnt of the technique from Euler, the author of [',' V I Lysenko, Differential equations in the works of A J Lexell (Russian), Istor.-Mat.
• Lexell did work in analysis on topics other than differential equations, for example he suggested a classification of elliptic integrals and he worked on the Lagrange series.

346. Aldo Ghizzetti (1908-1992)
• In addition to derivation of the basic properties of this transform, applications are indicated to ordinary linear differential equations with constant coefficients as well as systems of such equations.
• In the next three parts, the author applies the basic material to the solution of some of the ordinary and partial differential equations in electrotechnics.
• In part two, differential equations arising in lumped circuit phenomena are handled.
• After beginning work in Rome, his research interests moved towards the theory of moments and the theory of partial differential equations.

347. Tiberiu Popoviciu (1905-1975)
• Popoviciu made important contributions in Mathematical Analysis, Approximation Theory, Convexity, Numerical Analysis, Functional Equations, Algebra and Number Theory.
• Elena Popoviciu writes [',' E Popoviciu, Homage to the Memory of Academician Tiberiu Popoviciu, Annals of the Tiberiu Popoviciu Seminar of Functional Equations, Approximation and Convexity 3 (2005)','5]:- .
• Elena Popoviciu, who has a biography in this archive, is the author of [',' E Popoviciu, Homage to the Memory of Academician Tiberiu Popoviciu, Annals of the Tiberiu Popoviciu Seminar of Functional Equations, Approximation and Convexity 3 (2005)','5], [',' E Popoviciu, Hommage a la memoire de l’academicien Tiberiu Popoviciu, pour le centenaire de sa naissance, Rev.
• Some other achievements of Tiberiu Popoviciu were: the reactivation, in 1958, of the journal Mathematica (Cluj), the founding, in 1972, of the journal Revue d'Analyse Numerique et de Theorie de l'Approximation, and the opening, in 1967, of a research seminar: 'The Itinerant Seminar on Functional Equations', later renamed as 'The Itinerant Seminar on Functional Equations, Approximation and Convexity'.

348. Aleksandr Yakovlevich Povzner (1915-2008)
• At this stage in his career, however, his interests changed from algebra to analysis and his first publication in his new area of research was Sur les equations du type de Sturm-Liouville et les fonctions "positives" Ⓣ (1944).
• This did not prevent him continuing to undertake research and he published On equations of the Sturm-Liouville type on a semi-axis (1946) and a joint paper with Boris Moiseevich Levitan in the same year entitled Differential equations of the Sturm-Liouville type on the semi-axis and Plancherel's theorem.
• He also worked on partial differential equations which describe non-stationary processes.
• Systems of ordinary differential equations.
• Partial differential equations.

• Ważewski made important contributions to the theory of ordinary differential equations, partial differential equations, control theory and the theory of analytic spaces.
• was to bring him fame and lead to the development of a new school of differential equations.
• he succeeded in applying with amazing effect the topological notion of retract (introduced by K Borsuk) to the study of the solutions of differential equations.
• Lefschetz considered his method of retracts one of the most important achievements in the theory of differential equations since the war.

350. Fritz John (1910-1994)
• He applied this in his study of general properties of linear partial differential equations, convex geometry and the mathematical theory of water waves.
• It was in this period that John introduced the space of functions of bounded mean oscillations which plays a fundamental role in harmonic analysis and nonlinear elliptic equations.
• He retired in 1981 but at this time his work was concentrating on the theory of nonlinear wave equations.
• For anyone interested in the analysis of partial differential equations, the work of Fritz John is especially rewarding.
• He wrote by now classical papers in convexity, ill-posed problems, the numerical treatment of partial differential equations, quasi-isometry and blow-up in nonlinear wave propagation.

351. Juha Heinonen (1960-2007)
• Three were written jointly with Tero Kilpelainen: A-superharmonic functions and supersolutions of degenerate elliptic equations; Polar sets for supersolutions of degenerate elliptic equations; and On the Wiener criterion and quasilinear obstacle problems.
• The others were the single author publications Boundary accessibility and elliptic harmonic measures and Asymptotic paths for subsolutions of quasilinear elliptic equations, and the paper On quasiconformal rigidity in plane and space written with K Astala.
• Heinonen published two important books: (with Olli Martio and Tero Kilpelainen) Nonlinear Potential Theory of Degenerate Elliptic Equations (1993); and Lectures on Analysis on Metric Spaces (2001).
• This excellent book is the first monograph dealing with a potential theory of second-order quasilinear elliptic equations of [a certain] type ..

352. Einar Carl Hille (1894-1980)
• Kirsti Hille wrote the article [',' K Hille, Einar’s last journey, Integral Equations Operator Theory 4 (3) (1981), 304-306.','5] after the death of her husband.
• Hille's main work was on integral equations, differential equations, special functions, Dirichlet series and Fourier series.
• Among Hille's other texts were Analytic function theory Vol 1 (1959), Vol 2 (1964); Analysis Vol 1 (1964), Vol 2 (1966); Lectures on ordinary differential equations (1969); Methods in classical and functional analysis (1972); and Ordinary differential equations in the complex domain (1976).

353. Elemér Kiss (1929-2006)
• His first papers were on algebraic equations and polynomials.
• He published two papers in Romanian, namely Common roots of an arbitrary number of algebraic equations of higher order (1966) and A theorem of Hurwitz type (1967).
• The first of these gives theorems specifying necessary and sufficient conditions for n - k equations each of degree n to have k + 1 common roots, 0 ≤ k ≤ n - 1.
• Finally, we note that Bolyai worked on the solvability of polynomial equations and the fundamental theorem of algebra.
• In the paper under review, the author discusses the results of Bolyai on Fermat's little theorem, pseudoprime and Mersenne numbers, and Diophantine and exponential Diophantine equations.

354. Emory McClintock (1840-1916)
• One paper treats difference equations as differential equations of infinite order and others look at quintic equations which are soluble algebraically.
• This led he to restate difference equations as differential equations of infinite order.

355. Alexis Clairaut (1713-1765)
• The following year Clairaut studied the differential equations now known as 'Clairaut's differential equations' and gave a singular solution in addition to the general integral of the equations.
• In 1739 and 1740 he published further work on the integral calculus, proving the existence of integrating factors for solving first order differential equations (a topic which also interested Johann Bernoulli, Reyneau and Euler).
• The algebra book was an even more scholarly work and took the subject up to the solution of equations of degree four.

356. James Pierpont (1866-1938)
• Two series of lectures were given, one by Maxime Bocher on Linear Differential Equations, and their Application and the other by Pierpont on Galois's Theory of Equations.
• He also wrote some good historical articles on the theory of equations such as Lagrange's place in the theory of substitutions (1894), and Early history of Galois' theory of equations (1897).
• On the other hand the author, having in mind the needs of the students of applied mathematics, has dwelt at some length on the theory of linear differential equations, especially as regards the functions of Legendre, Laplace, Bessel, and Lame.

357. Mischa Cotlar (1913-2007)
• Jose Luis Massera writes [',' J L Massera, Mischa in Montevideo, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxi-xxiv.','13]:- .
• Luis Massera writes that [',' J L Massera, Mischa in Montevideo, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxi-xxiv.','13]:- .
• He met Manuel Sadosky who wrote [',' M Sadosky, My friend Mischa Cotlar, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxv-xxvii.','17]:- .
• There was another possibility [',' M Sadosky, My friend Mischa Cotlar, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxv-xxvii.','17]:- .
• We would like to quote here Calderon's description to Cotlar's mathematical contributions [',' A P Calderon, Introduction of Professor Mischa Cotlar to the National Academy of Exact Sciences of Argentina, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xix-xx.','5]:- .

358. Erich Hans Rothe (1895-1988)
• At the same time he undertook research for his doctorate on analogies between linear partial differential equations and linear ordinary differential equations.
• He helped to guide many brilliant students to the Ph.D., His contributions to mathematical research reflect his great breadth: differential and integral equations, linear and nonlinear functional analysis, topology, calculus of variations.
• If one seeks a guiding thread through his many papers, it is perhaps the extension to general spaces of the ideas of elementary calculus, in order to answer basic questions arising in partial differential equations and integral equations.

359. Kollagunta Ramanathan (1920-1992)
• Another fascinating paper is Ramanujan's modular equations (1990).
• The present author commences with a very informative historical survey of modular equations.
• Of course, in a paper of only 18 pages in length, the author can only discuss a small portion of Ramanujan's modular equations and he concentrates therefore on equations of composite degree.
• He gives some proofs, shows connections to previous work, and offers insights into how Ramanujan may have discovered some of his equations.

360. Joseph Serret (1819-1885)
• Serret also published papers on number theory, calculus, the theory of functions, group theory, mechanics, differential equations and astronomy.
• The first section contains the general theory of equations and the principles on which their numerical solution is based; in particular a highly developed theory of continued fractions can be found in this first section.
• The second section comprises the theory of symmetric functions, that of alternating functions and of determinants, and the many issues related to them, with important applications to the general theory of equations.
• The third section aims to give all the properties of integers that are essential in the theory of the algebraic resolution of equations; we find in this section a complete and new study of entire functions of one variable taken with respect to a first module.
• Finally I gather together in the fifth Section everything that relates directly to the algebraic solution of equations.

361. Henri Mineur (1899-1954)
• While still at High School, preparing for the second part of his degree, Henri Mineur had developed a passion for functional equations.
• There are remarks such as "the superiority of functional equations over differential equations is that they allow one to define discontinuous functions." .
• He was awarded his doctorate in 1924 for his thesis Discontinuous solutions of a class of functional equations in which he established an addition theorem for Fuchsian functions.
• It gives one of the very few up-to-date discussions of the subject, which is not merely intended for the layman or the general public, but treats the entire problem concisely, "from the ground up," using directly the equations of Einstein, de Sitter, Lemaitre, and others, and discusses the properties of the various types of space resulting from each.

362. William Spence (1777-1815)
• Spence published his last work "Outlines of a theory of algebraical equations: deduced from the principles of Harriot, and extended to the fluxional or differential calculus" in 1814.
• It is clear that Spence must have read Lagrange's 1770 paper Reflexions sur la resolution algebrique des equations for he tries to make a systematic approach to solving equations of degree 2, 3 and 4 using symmetrical functions of the roots as does Lagrange.
• This makes it sound as if Spence follows Lagrange rather closely but this is certainly not the case for he gives his own approach to solving these equations.
• Of course he has no success when he tries to generalise his approach to solving fifth degree equations.
• Of these tracts, the first only was intended by the author to meet the public eye in its present shape, though a few copies of another of them, demominated 'Outlines of a Theory of Algebraical Equations', had been printed and distributed among the author's friends.

363. Linards Reizins (1924-1991)
• He graduated in 1948 with distinction and became a member of the Department of Mathematical Analysis at the University while he undertook research on differential equations under Arvids Lusis.
• However, he continued to undertake research in mathematics and in 1951 his first paper The behaviour of the integral curves of a system of three differential equations in the neighbourhood of a singular point was published by the Latvian Academy of Sciences.
• thesis he studied the qualitative behaviour of homogeneous differential equations and obtained results that were highly regarded by specialists.
• Of the many other important contributions made by Reizins we should mention in particular his work on Pfaff's equations and his contributions to the history of mathematics.
• Other important historical papers include Mathematics in University of Latvia 1919-1969 (1975, joint with E Riekstins) and From the History of the General Theory of Ordinary Differential Equations (1977).

364. Karl Peterson (1828-1881)
• The dissertation contains a derivation of two equations equivalent to those of Mainardi and Codazzi, and in it Peterson outlined a proof of the fundamental theorem of surface theory.
• In [',' E R Phillips, Karl M Peterson : the earliest derivation of the Mainardi-Codazzi equations and the fundamental theorem of surface theory, Historia Math.
• His main work is in differential geometry but he obtained an honorary doctorate for his work on partial differential equations.
• This was in 1879 from the Novorossiiskii University of Odessa in recognition for his outstanding contributions to the theory of characteristics of partial differential equations [',' A T Grigorian, A P Youschkevitch, Biography in Dictionary of Scientific Biography (New York 1970-1990).
• by means of a uniform general method, he deduced nearly all the devices known at that time for finding general solutions of different classes of equations.
• These included: Sur l'integration des equations aux derivees partielles Ⓣ; Sur la deformation des surfaces du second ordre; Sur les courbes tracees sur les surfaces Ⓣ; and Sur les relations et les affinites entre les surfaces courbes Ⓣ.

365. Evgeny Remez (1896-1975)
• He gave courses at these institutions on analysis, differential equations and differential geometry while undertaking research for his doctorate.
• from Kiev State University in 1929 with his thesis Methods of Numerical Integration of Differential Equations with an Estimate of Exact Limits of Allowable Errors.
• Remez generalised Chebyshev-Markov characterisation theory and used it to obtain approximate solutions of differential equations.
• He also worked on approximate solutions of differential equations and the history of mathematics.
• The book has two parts: Part I - Properties of the solution of the general Chebyshev problem; Part II - Finite systems of inconsistent equations and the method of nets in Chebyshev approximation.

366. Pierre Deligne (1944-)
• He also worked closely with Jean-Pierre Serre, leading to important results on the l-adic representations attached to modular forms, and the conjectural functional equations of L-functions.
• Andre Weil gave for the first time a theory of varieties defined by equations with coefficients in an arbitrary field, in his Foundations of Algebraic Geometry (1946).
• Weil's work on polynomial equations led to questions on what properties of a geometric object can be determined purely algebraically.
• Weil's work related questions about integer solutions to polynomial equations to questions in algebraic geometry.
• He conjectured results about the number of solutions to polynomial equations over the integers using intuition on how algebraic topology should apply in this novel situation.

367. Alfredo Capelli (1855-1910)
• In this course Battaglini followed the approach given by Camille Jordan in his Traite des substitutions et des equations algebraique Ⓣ which he published in 1870.
• Capelli had proved the theorem, known today as the Rouche-Capelli theorem, which gives conditions for the existence of the solution of a system of linear equations.
• In 1879 Frobenius defined the rank of a system of equations to be the maximal order of a nonzero minor.
• In 1886 Capelli and Garbieri in Corso di analisi algebrica Ⓣ showed that a system of equations having rank k is equivalent to a triangular system with exactly k nonzero diagonal terms.
• This approach is very important in effective methods for solving systems of linear equations ..
• They also showed that a system of equations is consistent if and only if the rank of the array of its coefficients is the same as the rank of the array augmented by the row of constant terms.

368. Ronald Mitchell (1921-2007)
• He worked on an idea of Ron's of incorporating higher derivatives into methods for Ordinary Differential Equations, apparently one of the few times Ron strayed away from PDE's to ODE's.
• He was mainly interested at that time in finite difference methods for both ordinary and partial differential equations.
• He was joined in March 1964 by Donald Kershaw, whose main interests were differential and integral equations, and some students, including Alistair Watson.
• In this talk Olec Zienkiewicz described instabilities they had experienced in converting their successful finite element codes for structural problems into codes for solving the Navier-Stokes and related equations in fluid dynamics.
• Some of the problems arose from Mathematical Biology, on which "Mano" Manoranjan did much of his PhD work, but Ron was also interested in solitons, particularly those arising from the Korteweg-de Vries and Schrodinger equations.

369. Pierre Wantzel (1814-1848)
• Wantzel is famed for his work on solving equations by radicals.
• In 1845 Wantzel, continuing his researches into equations, gave a new proof of the impossibility of solving all algebraic equations by radicals.
• In meditating on the researches of these two mathematicians, and with the aid of principles we established in an earlier paper, we have arrived at a form of proof which appears so strict as to remove all doubt on this important part of the theory of equations.
• It was he who first gave the integration of differential equations of the elastic curve.

370. Francis Murnaghan (1893-1976)
• Harry Bateman had been appointed there in 1912 and his interests in partial differential equations fitted perfectly with Murnaghan's interests at the time.
• Arriving at Johns Hopkins University in Baltimore, Murnaghan began doctoral studies working on differential equations which arose in the study of radio-active decay.
• Of course this meant that he was deeply involved in solving differential equations, and indeed he also wrote papers on this topic.
• It covers topics such as: vectors and matrices; Fourier series; boundary value problems; Legendre and Bessel functions; integral equations; the calculus of variations and dynamics; and the operational calculus.
• The first of these is a short book of less that 100 pages written for engineers and scientists, while the second consists of 19 lectures on such topics as: the Fourier integral; the Laplace integral transformation; the differential equations of Laguerre and Bessel; properties of special functions; asymptotic series for an error function, and for certain Bessel functions.

371. Alonzo Church (1903-1995)
• Early contributions included the papers On irredundant sets of postulates (1925), On the form of differential equations of a system of paths (1926), and Alternatives to Zermelo's assumption (1927).
• For example he published Remarks on the elementary theory of differential equations as area of research in 1965 and A generalization of Laplace's transformation in 1966.
• The first examines ideas and results in the elementary theory of ordinary and partial differential equations which Church feels may encourage further investigation of the topic.
• The paper includes a discussion of a generalization the Laplace transform which he extends to non-linear partial differential equations.
• This generalization of the Laplace transform is the topic of study of the second paper, again using the method to obtain solutions of second-order partial differential equations.

372. Paul Gordan (1837-1912)
• Moving to Konigsberg, Gordan studied under Jacobi, then he moved to Berlin where he began to become interested in problems concerning algebraic equations.
• In the year 1874-75 when Gordan and Klein were together at Erlangen they undertook a joint research project examining groups of substitutions of algebraic equations.
• They investigated the relationship between PSL(2,5) and equations of degree five.
• Later Gordan went on to examine the relation between the group PSL(2,7) and equations of degree seven, then he studied the relation of the group A6 to equations of degree six.

373. John Wallis (1616-1703)
• He also discovered methods of solving equations of degree four which were similar to those which Harriot had found but Wallis claimed that he made the discoveries himself, not being aware of Harriot's contributions until later.
• He also criticises Descartes' Rule of Signs stating, quite correctly, that the rule which determines the number of positive and the number of negative roots by inspection, is only valid if all the roots of the equation are real.
• History Topics: Pell's equation .

374. George Stokes (1819-1903)
• After he had deduced the correct equations of motion Stokes discovered that again he was not the first to obtain the equations since Navier, Poisson and Saint-Venant had already considered the problem.
• The work also discussed the equilibrium and motion of elastic solids and Stokes used a continuity argument to justify the same equation of motion for elastic solids as for viscous fluids.

375. Philip Franklin (1898-1965)
• While still an undergraduate, Franklin was taking part in published discussions in The American Mathematical Monthly, his contribution to the Discussion: Relating to the Real Locus Defined by the Equation xy = yx appearing in March 1917.
• However, he is best known for textbooks he published on calculus, differential equations, complex variable and Fourier series.
• In particular he wrote Differential equations for electrical engineers (1933), Treatise on advanced calculus (1940), The four color problem (1941), Methods of advanced calculus (1944), Fourier methods (1949), Differential and integral calculus (1953), Functions of a complex variable (1958) and Compact calculus (1963).

376. Mitchell Feigenbaum (1944-)
• In 1973 it had been conjectured that the behaviour of the logistic equation was the same in a qualitative sense for all g(x) which have a maximum value and decrease monotonically on either side of this maximum.
• The remarkable result obtained by Feigenbaum was to show that not only was the behaviour qualitatively similar but there was a very precise mathematical result which held for all such logistic equations.
• Feigenbaum did not actually work with the precise logistic equation which May studied and in fact his work was independent of that by May.

• In "Elements" Legendre gave a simple proof that π is irrational, as well as the first proof that π2 is irrational, and conjectured that π is not the root of any algebraic equation of finite degree with rational coefficients.
• I have thought that what there was better to do in the problem of comets was to start out from the immediate data of observation, and to use all means to simplify as much as possible the formulas and the equations which serve to determine the elements of the orbit.
• His method involved three observations taken at equal intervals and he assumed that the comet followed a parabolic path so that he ended up with more equations than there were unknowns.

• He discussed the concepts of quantum groups and quantization, and also talked about Poisson groups, Lie bi-algebras and the classical Yang-Baxter equation.
• The interactions between mathematics and mathematical physics studied by Atiyah led to the introduction of instantons - solutions, that is, of a certain nonlinear system of partial differential equations, the self-dual Yang-Mills equations, which were originally introduced by physicists in the context of quantum field theory.

379. Cahit Arf (1910-1997)
• At that time, I was thinking about making a list of the algebraic equations or Galois algebraic equations that could be solved.
• Arf presented a paper On a generalization of Green's formula and its application to the Cauchy problem for a hyperbolic equation to the volume Studies in mathematics and mechanics presented to Richard von Mises in 1954.

380. Ernest Vessiot (1865-1952)
• In 1892 he submitted his doctoral dissertation Sur l'integration des equations differentielles lineaires Ⓣ.
• In this he studied Lie groups of linear transformations, in particular considering the action of these Lie groups on the independent solutions of a differential equation.
• He published his thesis in the Annales Scientifiques de l'Ecole Normale Superieure in 1892 and over the following few years published papers such as Sur une classe d'equations differentielles Ⓣ (1893), Sur une methode de transformation et sur la reduction des singularites d'une courbe algebrique Ⓣ (1894), Sur les systemes d'equations differentielles du premier ordre qui ont des systemes fondamentaux d'integrales Ⓣ (1894), and Sur quelques equations differentielles ordinaires du second ordre Ⓣ (1895).
• As we mentioned above, Vessiot applied continuous groups to the study of differential equations.
• He extended results of Jules Joseph Drach (1902) and Elie Cartan (1907) and also extended Fredholm integrals to partial differential equations.

381. Rudolf Clausius (1822-1888)
• The basic equation set up by Clausius was therefore dQ = dU + dW where dQ was the increment in the heat, dU was the change in energy of the body, and dW was the change in external work done.
• The Clausius-Clapeyron equation appears which expresses the relation between the pressure and temperature at which two phases of a substance are in equilibrium.
• Clausius deliberately made choices in setting up the equations so that they were:- .

382. Tom Cowling (1906-1990)
• The equations of Boltzmann and Maxwell are then developed, Enskog's generalization of Maxwell's equation of transfer being given.
• In the important chapter on the non-uniform state for a simple gas, use is made of Enskog's method of solving the integral equation and of Burnett's calculation of certain quantities A and B with the aid of Sonine's polynomials.

383. Robert May (1936-)
• Let us give a few examples of papers he published (some as joint publications): Susceptibility of superconducting spheres (1959); Meissner-Ochsenfeld effect in the Bogolyubov theory (1959); Gauge invariance in the theory of superconductivity (1959); Superconductivity of a charged ideal 2-dimensional Bose gas (1959); Quantum statistics of ideal gases in two dimensions (1964); Relaxation of a fast ion in a plasma (1964); Magnetic properties of charged ideal quantum gases in n dimensions (1965); Exact equation of state for a 2-dimensional plasma (1967); Electron scattering and tests of cosmological models (1968); The rate of the proton-proton reaction and some related reactions (1969).
• First-order difference equations arise in many contexts in biological, economic and social sciences.
• Such equations, even though simple and deterministic, can exhibit a surprising array of dynamical behaviour, from stable points, to bifurcating hierarchy of stable cycles, to apparently random fluctuations.

384. Cândido Silva Dias (1913-1998)
• In the same seminar in 1938, he presented the theory of continuous groups applied to differential equations.
• On 6 July 1943 Silva Dias presented the work "Application of the theory of the analytical functionals to the study of a solution for a differential equation of infinite order" to the Brazilian Academy of Sciences, communicated by Francisco de Oliveira Castro, which was published in its Annals.
• In the same year Theorems of Existence in Differential Equations was published.

385. Helge von Koch (1870-1924)
• Von Koch's first results were on infinitely many linear equations in infinitely many unknowns.
• In 1891 he wrote the first of two papers on applications of infinite determinants to solving systems of differential equations with analytic coefficients.
• Yet this work can be said to be the first step on the long road which eventually led to functional analysis, since it provided Fredholm with the key for the solution of his integral equation.

386. Phyllis Nicolson (1917-1968)
• Phyllis Nicolson is best known for her joint work with John Crank on the heat equation, where a continuous solution u(x, t) is required which satisfies the second order partial differential equation .
• Crank and Nicolson's method, which is numerically stable, requires the solution of a very simple system of linear equations (a tridiagonal system) at each time level.

• The first of these papers gives an existence theorem for the equation zx = f (x, y, z, zy) using methods which had been developed by Baiada a couple of years earlier in solving a simpler equation.
• We have mentioned some of Baiada's publications above but we note that his output totals 60 scientific publications on a wide range of different fields in analysis: ordinary and partial differential equations, Fourier series and the series expansion of orthonormal functions, topology, real analysis, functional analysis, calculus of variations, measure and integration, optimisation, and the theory of functions.

388. George Hill (1838-1914)
• Examples of papers he published in the Annals of Mathematics include: On the lunar inequalities produced by the motion of the ecliptic (1884), Coplanar motion of two planets, one having a zero mass (1887), On differential equations with periodic integrals (1887) (these differential equations are now called Hill's differential equation), On the interior constitution of the earth as respects density (1888), The secular perturbations of two planets moving in the same plane; with application to Jupiter and Saturn (1890), On intermediate orbits (1893), Literal expression for the motion of the Moon's perigee (1894) and Application of Chebyshev's principle in the projection of maps (1908).

389. Federico Cafiero (1914-1980)
• His next paper was Un'osservazione sulla continuita rispetto ai valori iniziali degli integrali dell'equazione: y' = f (x, y) (1947), which proves that any group of conditions sufficient to assure the existence and uniqueness, with respect to the initial values, of the integral of the equation y' = f (x, y) is also sufficient to assure the continuous dependence of the solution on the initial values.
• In each of the years 1948, 1949 and 1950, Cafiero published three papers most of which studied ordinary differential equations.
• We have already seen that Cafiero made contributions to the theory of ordinary differential equations and to the theory of measure and integration.

390. Jan Stampioen (1610-1690)
• In 1633 he challenged Descartes to a public competition by giving him a geometric problem whose solution involved the solution of a quartic equation.
• In fact Stampioen's criticism was fair for although Descartes had taken the geometric problem and derived the correct quartic equation, he left the problem there without solving the quartic.
• The problem which Stampioen was interested in came as a consequence of using the Cardan-Tartaglia formula to solve cubic equations.

391. Arthur Coble (1878-1966)
• His interests in research relate to finite geometries and the group theory related to them, and to Cremona transformations related to the Galois theory of equations.
• His early papers, written while he was at Johns Hopkins University, include: On the relation between the three-parameter groups of a cubic space curve and a quadric surface (1906); An application of the form-problems associated with certain Cremona groups to the solution of equations of higher degree (1908); An application of Moore's cross-ratio group to the solution of the sextic equation (1911); An application of finite geometry to the characteristic theory of the odd and even theta functions (1913); and Point sets and allied Cremona groups (1915).

392. Miroslav Fiedler (1926-2015)
• He published his thesis in three parts (1954, 1955, 1956) but these were not his first publications, having already published Solution of a problem of Professor E Cech (1952), On certain matrices and the equation for the parameters of singular points of a rational curve (1952), and (with L Granat) Rational curve with the maximum number of real nodal points (1954).
• Examples of papers he published on these topics are: Numerical solution of algebraic equations which have roots with almost the same modulus (1956); Numerical solution of algebraic equations by the Bernoulli-Whittaker method (1957); On some properties of Hermitian matrices (1957); (with Jiri Sedlacek) On W-bases of directed graphs (1958); and (with Josej Bily and Frantisek Nozieka) Die Graphentheorie in Anwendung auf das Transportproblem Ⓣ (1958).

393. Ernest Wilkins (1923-2011)
• In 1944 four of his papers appeared: On the growth of solutions of linear differential equations; Definitely self-conjugate adjoint integral equations; Multiple integral problems in parametric form in the calculus of variations; and A note on skewness and kurtosis.
• In the following year he published The differential difference equation for epidemics in the Bulletin of Mathematical Biophysics.

394. József Kürschák (1864-1933)
• Another topic which Kurschak investigated was the differential equations of the calculus of variations.
• He proved invariance of the differential equations he was considering under contact transformations.
• a second-order differential expressions to provide the equation belonging to the variation of a multiple integral.

395. Gary Roach (1933-2012)
• His early papers were: On the approximate solution of elliptic, self adjoint boundary value problems (1967); Fundamental solutions and surface distributions (1968); Approximate Green's functions and the solution of related integral equations (1970); and (jointly with Robert A Adams) An intrinsic approach to radiation conditions (1972).
• As indicated by the title, this book is intended to give a self-contained and systematic introduction to the theory of Green's functions and the general ideas involved in their application to boundary value problems associated with ordinary and partial differential equations.
• The required preliminaries do not exceed an elementary knowledge of the initial-boundary value problem for the wave equation.

396. Ágoston Scholtz (1844-1916)
• They considered projective geometrical questions about conic sections and they transformed these questions into algebraic equations, where the determinant came into play.
• In Six points lying on a conic section, and the theorem hexagrammum mysticum (1877) and Sechs Punkte eines Kegelschnittes (1878) he proved Pascal's theorem in Steiner's generality, by reducing it to an equation involving certain determinants.
• Scholtz' later papers appeared in the Nouvelle Annales de Mathematique, for example Resolution de l'equation du troisieme degre Ⓣ (1881), and in the Yearbook of the Grammar School in Iglo, see A remark on light interference (1886).

397. Jan A Schouten (1883-1971)
• He produced 180 papers and 6 books on tensor analysis, applying tensor analysis to Lie groups, general relativity, unified field theory, and differential equations.
• This is a complete exposition of the classical theory of the Pfaffian equation and of the present results in the theory of systems of Pfaffian equations, to which the authors themselves have substantially contributed.

398. Giuseppe Peano (1858-1932)
• In 1886 Peano proved that if f (x, y) is continuous then the first order differential equation dy/dx = f (x, y) has a solution.
• Four years later Peano showed that the solutions were not unique, giving as an example the differential equation dy/dx = 3y2/3 , with y(0) = 0.
• The following year he discovered, and published, a method for solving systems of linear differential equations using successive approximations.

399. Rafael Laguardia (1906-1980)
• Jose Luis Massera describes joining and participating in Laguardia's group in [',' J L Massera, Mischa in Montevideo, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxi-xxiv.','3]:- .
• One result of his visit was the joint paper he published with Beppo Levi entitled On the representation by integrals of some functions defined by Taylor expansions and its application to the solution of partial differential equations (Spanish).
• Massera wrote in [',' J L Massera, Mischa in Montevideo, in C Sadosky (ed.), Analysis and partial differential equations: A collection of papers dedicated to Mischa Cotlar (Marcel Decker, Inc., New York and Basel, 1990), xxi-xxiv.','3]:- .

400. Diederik Korteweg (1848-1941)
• On this topic he published Sur la forme que prennent les equations du mouvement des fluids si l'on tient compte des forces capillaires causes par les variations de densite Ⓣ in 1901.
• He is remembered in particular for the Korteweg - de Vries equation on solitary waves, a courageous topic to attack since many mathematicians, including Stokes, were convinced such waves could not exist.
• They found explicit, closed-form, travelling-wave solutions to the Korteweg - de Vries equation that decay rapidly.
• We can mention, again showing Korteweg's versatility, his pure mathematics work on algebraic equations in papers such as Sur un theoreme remarquable, qui se rapporte a la theorie des equations algebriques a parametres reels, dont toutes les racines restent constamment reelles Ⓣ (1900).

401. Roger Apéry (1916-1994)
• However, in the 1950s he became interested in number theory and worked on diophantine equations.
• In particular he studied the diophantine equation .
• Two short papers, both entitled Sur une equation diophantienne Ⓣ, are devoted to a study of this equation.

402. Karl von Staudt (1798-1867)
• Von Staudt also gave a nice geometric solution to quadratic equations.
• We are given the quadratic equation x2 - gx + h = 0 which we wish to solve geometrically.
• Then a and b are the roots of the given quadratic equation.

403. Georgy Voronoy (1868-1908)
• He was awarded a Master's Degree in 1894 for a dissertation on the algebraic integers associated with the roots of an irreducible cubic equation.
• In the essay I am now presenting, results from the general theory of algebraic integers are applied to the particular case of numbers depending on the root of an irreducible equation x3 = rx + s.
• In our exposition the resolution of these questions is based on a detailed study of the solutions of third-degree equations relative to a prime and a composite modulus.

404. James Joseph Sylvester (1814-1897)
• He was a very active researcher and by the time he resigned the chair of natural philosophy in 1841 he had published fifteen papers on fluid dynamics and algebraic equations.
• In 1851 he discovered the discriminant of a cubic equation and first used the name 'discriminant' for such expressions of quadratic equations and those of higher order.

405. Delfino Codazzi (1824-1873)
• The formulas give two relations between the first and second quadratic forms over a surface together with an equation, already found by Gauss, which gives necessary and sufficient conditions for the existence of a surface which admits two given quadratic forms.
• The article [',' E R Phillips, Karl M Peterson : the earliest derivation of the Mainardi-Codazzi equations and the fundamental theorem of surface theory, Historia Math.
• 6 (2) (1979), 137-163.','3] shows that, in 1853, Karl M Peterson, then a student of Minding at the University of Dorpat (now named Tartu), submitted a dissertation containing a derivation of two equations equivalent to those of Mainardi and Codazzi and outlining a proof of the fundamental theorem of surface theory.

406. Jakob Hermann (1678-1733)
• He lectured on mechanics in November 1708 and in December of that year he wrote to Grandi giving him a detailed explanation of how to use Leibniz's calculus to deduce the differential equation of the logarithm function.
• Hermann discussed such topics as finding the radius of curvature and normals to plane curves; the division of an angle or an arc of a circumference into n parts, by the use of an infinite series; orthogonal trajectories for a given family of curves, by the use of differential equations; and the use of polar coordinates in the analysis of plane curves other than spirals.
• In his work on curves in space, Hermann discusses the spherical epicycloid; the problem of finding the shortest distance between two points on a given surface; and the equations and properties of various surfaces from the point of view of analytic geometry of three dimensions.

407. René Descartes (1596-1650)
• Harriot's work on equations, however, may indeed have influenced Descartes who always claimed, clearly falsely, that nothing in his work was influenced by the work of others.
• Descartes' geometric solution of a quadratic equation .
• History Topics: Quadratic etc equations .

408. Jacqueline Ferrand (1918-2014)
• Pierre Lelong's name is attached to several mathematical concepts, for example the Poincare-Lelong equation, the Lelong-Demailly numbers, Lelong's problem, and the Lelong-Skoda transform.
• Volume III covered multivariable integral calculus, further topics in functions of a complex variable, Fourier series and ordinary differential equations.
• The fourth and final volume was published in 1974 and covered ordinary differential equations, multivariable integral calculus and holomorphic functions.

409. Horst Tietz (1921-2012)
• Erich Hecke, although he was mortally ill, lectured on Linear Differential Equations.
• The 1953 paper Die Kinematik des starren Korpers Ⓣ was a joint work with Rudolf Iglisch in which the authors derive Euler's equation in kinematics by means of vector algebra.
• Differential equations; 8.

410. George Jeffery (1891-1957)
• He did one years teacher training in 1911 but he was already undertaking research and his first paper On a form of the solution of Laplace's equation suitable for problems relating to two spheres was read to the Royal Society in 1912.
• He made effective use of Whittaker's general solution to Laplace's equation which Whittaker found in 1903.
• Jeffery also worked on general relativity and produced exact solutions to Einstein's field equations in certain special cases.

411. Sripati (1019-1066)
• His work on equations in this chapter contains the rule for solving a quadratic equation and, more impressively, he gives the identity: .
• Other mathematics included in Sripati's work includes, in particular, rules for the solution of simultaneous indeterminate equations of the first degree that are similar to those given by Brahmagupta .

412. Lyman Spitzer (1914-1997)
• A rapid treatment of the Boltzmann equation, in an appendix, brings us in Chapter 2 to the transport equation for a fluid.
• This is joined with Maxwell's equations, and the simple limits of high and low magnetic fields are briefly considered.

413. Griffith Evans (1887-1973)
• His doctoral dissertation Volterra's integral equation of the second kind with discontinuous kernel was published in the Transactions of the American Mathematical Society in two parts in 1910 and 1911.
• His work dealt with potential theory, functional analysis, integral equations and the problem of minimal surfaces, the Plateau Problem.
• Among the important texts he wrote were Functional equations and their applications (1918), The logarithmic potential (1927), and Mathematical Introduction to economics (1930).

414. William Osgood (1864-1943)
• Osgood's main work was on the convergence of sequences of continuous functions, solutions of differential equations, the calculus of variations and space filling curves.
• In 1898 Osgood published an important paper on the solutions of the differential equation dy/dx = f (x, y) satisfying the prescribed initial conditions y(a) = b.
• Some papers over the next few years included: Sufficient conditions in the calculus of variations (1900), On a fundamental property of a minimum in the calculus of variations and the proof of a theorem of Weierstrass's (1901), A Jordan curve of positive area (1903), On Cantor's theorem concerning the coefficients of a convergent trigonometric series, with generalizations (1909), On the gyroscope (1922), and On normal forms of differential equations (1925).

415. Freeman Dyson (1923-)
• The first, written in 1941 (published in 1944) is A proof that every equation has a root.
• there are so many proofs of the theorem that every equation has a root that it seems almost criminal to produce another.
• The historical account of the breakdown in communications between mathematicians and physicists and of the lack of interest in Maxwell's equations constitutes an indictment of the mathematical community.

416. Julius Plücker (1801-1868)
• The characteristic features of Plucker's analytic geometry were already present in this work, namely, the elegant operations with algebraic symbols occurring in the equations of conic sections and their pencils.
• This work also contains the celebrated 'Plucker equations' relating the order and class of a curve.
• In this way of specifying coordinates, a point has a linear equation, namely that of all lines through the point while a line has a pair of numbers namely the x and y coordinates of where it cuts the axes.

417. Eleanor Pairman (1896-1973)
• Her thesis advisor was George Birkhoff and after submitting her thesis Expansion Theorems for Solution of a Fredholm's Linear Homogeneous Integral Equation of the Second Kind with Kernel of Special Non-Symmetric Type she was awarded a Ph.D.
• Pairman joined the Edinburgh Mathematical Society in January 1917, and read the paper On a difference equation due to Stirling to the meeting of the Society on 11 January 1918, and the paper A new form of the remainder in Newton's interpolation formula to the next meeting of the Society on 8 February.
• In 1927 she published a joint mathematics paper On a class of integral equations with discontinuous kernels with Rudolph E Langer, who was a friend who graduated from Harvard in a June 1922 ceremony as Eleanor Pairman and Bancroft Brown and, like Eleanor, had George Birkhoff as his thesis advisor.

418. Alexander Friedmann (1888-1925)
• In his last year at the University he was working on an essay on the subject I assigned: 'Find all orthogonal substitutions such that the Laplace equation, transformed for the new variables, admits particular solutions in the form of a product of two functions, one of which depends only on one, and the other on the other two variables'.
• Also in this letter he asked Steklov's advice on integrating equations he had obtained from theoretically modelling bombs dropping.
• In reality it turns out that the solution given in it does not satisfy the field equations.

419. Alexander Oppenheim (1903-1997)
• Even at this stage it was number theory which appealed to him and he began solving Diophantine equations.
• He continued with his early interest in Diophantine equations and looked to apply methods coming from ergodic theory.
• Examples of his papers are Rational approximations to irrationals (1941), On the representation of real numbers by products of rational numbers (1953), On indefinite binary quadratic forms (1954), On the Diophantine equation x3+ y3+ z3= x + y + z (1966), The irrationality of certain infinite products (1968), Representations of real numbers by series of reciprocals of odd integers (1971) and The prisoner's walk: an exercise in number theory (1984).

• We give details below of Sridhara's rule for solving quadratic equations as given by Bhaskara II.
• Sridhara was one of the first mathematicians to give a rule to solve a quadratic equation.
• Multiply both sides of the equation by a known quantity equal to four times the coefficient of the square of the unknown; add to both sides a known quantity equal to the square of the coefficient of the unknown; then take the square root.

421. Nicolaus(I) Bernoulli (1687-1759)
• There he worked on geometry and differential equations.
• Other problems he worked on involved differential equations.
• He also made significant contributions in studying the Riccati equation.

422. Arnljot Høyland (1924-2002)
• They were given the task of solving 26 equations in 26 unknowns.
• Reiersøl suggested a topic on probability densities of specific differential equations.
• The differential equation took a whole page and so was utterly awful.

423. Hans Schubert (1908-1987)
• Uber eine lineare Integrodifferentialgleichung mit Zusatzkern Ⓣ (1950) looked at certain aerodynamical problems which lead to integrodifferential equations.
• At Halle Schubert taught a variety of different courses such as differential and integral calculus, partial differential equation, and integral equations.

424. Fibonacci (1170-1250)
• Indeed, although mainly a book about the use of Arab numerals, which became known as algorism, simultaneous linear equations are also studied in this work.
• Fibonacci proves that the root of the equation is neither an integer nor a fraction, nor the square root of a fraction.
• And because it was not possible to solve this equation in any other of the above ways, I worked to reduce the solution to an approximation.

425. Eugen Netto (1846-1919)
• It was in fact Weierstrass who examined his final 20-page doctoral dissertation, written in Latin, De transformatione aequationis yn = R(x), designante R(x) functionem integram rationalem variabilis x in aequationem η2 = R1(xi) n = R (x) designating \R (x) as a rational function of the variable x in the equation \ η2 = R1 (xi)',5725)">Ⓣ.

426. Ernst Mohr (1910-1989)
• From this time on his work was on applied mathematics, mainly fluid dynamics and differential equations, but he also published the occasional paper on polynomials.
• One of these 1951 papers looks at the numerical solution of the differential equation dy/dx = f (x, y).
• Hermann Weyl, in two pioneering papers, described a class of differential equations in the limit point case where complete determination of the continuous spectrum is possible.

• In the following years he taught Differential and Integral Calculus, Theory of Definite Integrals, Some chapters from mechanics and the calculus of variations, Higher Algebra, Differential Equation of Mechanics and the Calculus of Variations, Analytic Geometry, and many more courses of a similar type.
• Mayer worked on differential equations, the calculus of variations and mechanics.
• His work on the integration of partial differential equation and a search to determine maxima and minima using variational methods brought him close to the investigations which Lie was carrying out around the same time.

428. Herman Goldstine (1913-2004)
• Most of the paper is taken up with the more difficult problem of determining such conditions when the class of admissible points is (1940) required to satisfy an equation of an abstract functional character.
• There followed A generalized Pell equation.
• In particular the School used a Bush analyser, designed by Vannevar Bush, specifically to integrate systems of ordinary differential equations.

429. Michael Stifel (1487-1567)
• Also in this book he solves cubic and quartic equations using methods from Cardan.
• In particular, he solves the quartic equation .
• One of the advances in Stifel's notes is an early attempt to use negative numbers to reduce the solution of a quadratic equation to a single case.

• The geometric problems that al-Quhi studied usually led to quadratic or cubic equations.
• One, which requires the solution of a quadratic equation, had been found by Abu Kamil in the ninth century.
• The other, which requires the solution of a quartic equation, is the one presented by al-Quhi.

431. Karl Maruhn (1904-1976)
• In this last mentioned paper, Maruhn reminds the reader that the solutions of the boundary value problems for Laplace's equation are not unique when the boundary functions are allowed to assume infinite values.
• This summary contains a brief account of papers on (A) special solutions of the potential equation, (B) boundary value problems, (C) connections with boundary value problems for other differential equations, (D) connections with the theory of functions, (E) biharmonic functions.

432. Hitoshi Kumano-Go (1935-1982)
• His supervisor was M Nagumo who supervised his work on the singular perturbation of second order partial differential equations.
• During these years Kumano-Go published a series of papers which studied the local and global uniqueness of the solutions of the Cauchy problem for partial differential equations.
• This is Partial differential equations which was again written in Japanese and was published in 1978.
• This is a textbook which in addition to studying partial differential equations provides an introduction to pseudo-differential operators.

433. Eduard Weyr (1852-1903)
• The most important lecture course he attended was the Theory of Abelian Functions and the General Theory of Algebraic Equations by Alfred Clebsch but this was cut short in November 1872, only weeks after Weyr arrived, when Clebsch died suddenly of diphtheria.
• He lectured during session 1875-76 giving the two courses The theory of functions, and Elliptic equations.
• One of his most important results in algebra concerns bilateral equations, where Weyr generalised results of James Joseph Sylvester on the solution of unilateral equations.

434. Ferdinand Minding (1806-1885)
• Minding dropped the more delicate part of Gauss's theory of forms (genera, composition), but added things expected from the perspective of a textbook, for instance, linear Diophantine equations or continued fractions.
• wrote many important works not only on differential geometry but also in the theory of ordinary differential equations, in analytic mechanics (anticipating the geometrical treatment later developed by Beltrami and Lipschitz), in the calculus of variations (especially on the isoperimetric problem for curved surfaces), etc.
• Minding also worked on differential equations, algebraic functions, continued fractions and analytic mechanics.
• In differential equations he used integrating factor methods.

435. Barnabé Brisson (1777-1828)
• His favourite field of study was the theory of partial differential equations.
• The main idea in these reports was the application of the functional calculus, through symbols, to the solution of certain kinds of linear differential equations and of linear equations with finite differences.
• The 1823 report was the object of lively discussion in 1825 before the Academy and was approved of by Cauchy, who, although he had some reservations about the validity of some of the symbols used and the equations obtained, emphasized the elegance of the method and the importance of the objects to which they were applied.

436. Hyman Levy (1889-1975)
• Levy's main work was in numerical methods, numerical solution of differential equations, finite difference equations and statistics.
• Among other mathematical works he published were Numerical Studies in Differential Equations (1934), Elements of the Theory of Probability (1936), and Finite Difference Equations (1958).

• This is an important work in the theory of partial differential equations and was reprinted in Crelle's Journal in 1836 and an English translation was made by Todhunter and published in 1861.
• His important work on ordinary differential equations considered methods of solution of non-linear equations which involved power series expansions in a parameter alpha.
• In addition to his important contributions to partial differential equations, he made significant advances to the theory of elasticity and to algebra publishing over 80 reports and giving lectures.

438. George Szekeres (1911-2005)
• The reference to chaos theory here refers in particular to his interest in Feigenbaum's functional equation.
• Another unusual quality was George's interest in computational and "experimental" mathematics, which he maintained until his last paper on Abel's equation.
• In the mid-90s, I worked with him on Feigenbaum's functional equation.
• We wrote programs to solve several cases of this equation, and I was very impressed by this 80 year-old who knew more about how to actually get computers to do real mathematics than many of my younger colleagues.

439. Shreeram Shankar Abhyankar (1930-2012)
• A small example concerns the words 'analytic geometry', which stood at that time for the high school study of conic sections and their equations.
• Ram said nonsense, algebraic geometry is the study of the geometry of algebraic equations, so analytic geometry must be the study of the geometry of all real or complex analytic equations.
• Some specific areas encompassed in his vast research work are resolution of singularities, tame coverings and algebraic fundamental groups, affine geometry, enumerative combinatorics of Young tableaux and Galois groups and equations.

440. Leon Simon (1945-)
• in 1971 for his thesis Interior Gradient Bounds for Non-Uniformly Elliptic Equations.
• supervisor James H Michael) Sobolev and mean-value inequalities on generalized submanifolds of Rn (1973); Global estimates of Holder continuity for a class of divergence-form elliptic equations (1974); (with Richard M Schoen and Shing-Tung Yau) Curvature estimates for minimal hypersurfaces (1975); Interior gradient bounds for non-uniformly elliptic equations (1976); and Remarks on curvature estimates for minimal hypersurfaces (1976).
• This development began with his 1983 paper "Asymptotics for a class of nonlinear evolution equations, with applications to geometric problems." The first stage of his work on general singular sets is principally described in "Cylindrical tangent cones and the singular set of minimal submanifolds" (1993), and the remaining work appears in his paper "Rectifiability of the singular set of energy minimizing maps" (1995).

441. Gaspard Monge (1746-1818)
• The four memoirs that Monge submitted to the Academie were on a generalisation of the calculus of variations, infinitesimal geometry, the theory of partial differential equations, and combinatorics.
• Over the next few years he submitted a series of important papers to the Academie on partial differential equations which he studied from a geometrical point of view.
• .the composition of nitrous acid, the generation of curved surfaces, finite difference equations, partial differential equations (1785); double refraction and the structure of Iceland spar, the composition of iron, steel, and cast iron, and the action of electricity sparks on carbon dioxide gas (1786); capillary phenomena (1787); and the causes of certain meteorological phenomena (1788); and a study in physiological optics (1789).

442. James Cockle (1819-1895)
• Most of his work, however, was in pure mathematics where he studied algebra, the theory of equations, and differential equations.
• Describing Cockle's contributions to differential equations Harley explained that his [',' R Harley, James Cockle, Proc.
• mode of dealing with the theory of differential equations was marked by originality and independence of mind.

443. Roman Stanislaw Ingarden (1920-2011)
• For example his early work includes Equations of motion and field equations in five-dimensional unified relativity theory (Russian) (1953) in which he:- .
• The gravitational equations of the general relativity theory involving the energy-momentum density tensor of matter are generalized to five dimensions.
• Other papers by Ingarden around this time include: A generalization of the Young-Rubinowicz principle in the theory of diffraction (1955); On a new type of relativistically invariant linear local field equations (Russian) (1956); On the geometrically absolute optical representation in the electron microscope (1957); and Composite variational problems (1959) [',' A Jamiolkowski and R Mrugala, Roman Ingarden (1920-2011), Rep.

• The Book on algebra by Abu Kamil is in three parts: (i) On the solution of quadratic equations, (ii) On applications of algebra to the regular pentagon and decagon, and (iii) On Diophantine equations and problems of recreational mathematics.
• The Book of rare things in the art of calculation is concerned with solutions to indeterminate equations.
• Sesiano in [',' J Sesiano, Les methodes d’analyse indeterminee chez abu Kamil, Centaurus 21 (2) (1977), 89-105.','11] discusses Abu Kamil's work on indeterminate equations and he argues that his methods are very interesting for three reasons.

445. Ludwig Boltzmann (1844-1906)
• The equations of Newtonian mechanics are reversible in time and Poincare proved that if a mechanical system is in a given state it will return infinitely often to a state arbitrarily close to the given one.
• The actual irreversibility of natural phenomena thus proves the existence of processes that cannot be described by mechanical equations, and with this the verdict on scientific materialism is settled.
• Boltzmann continued to defend his belief in atomic structure and in a 1905 publication Populare Schriften Ⓣ he tried to explain how the physical world could be described by differential equations which represented the macroscopic view without representing the underlying atomic structure.
• May I be excused for saying with banality that the forest hides the trees for those who think that they disengage themselves from atomistics by the consideration of differential equations.

446. Germinal Dandelin (1794-1847)
• He gave a method of approximating the roots of an algebraic equation, now named the Dandelin-Graffe method, and published this in Recherches sur la resolution des equations numeriques Ⓣ (1826).
• Dandelin then considers the possibility of accelerating both processes by applying them to the equation whose roots are the squares of those of the original.
• The method he proposes for doing this is to form the product f (x) f (-x), where f (x) = 0 is the original equation (note that this is not quite the way one does it now).
• The first is that if the zeros of a polynomial are widely separated into one group of very large modulus, and one of very small modulus, then the equation which remains when final terms are dropped is approximately satisfied by the large zeros.

447. Jacob Bernoulli (1655-1705)
• In May 1690 in a paper published in Acta Eruditorum, Jacob Bernoulli showed that the problem of determining the isochrone is equivalent to solving a first-order nonlinear differential equation.
• After finding the differential equation, Bernoulli then solved it by what we now call separation of variables.
• In 1696 Bernoulli solved the equation, now called "the Bernoulli equation", .

• The topic proposed for the prize had been one on geodesics and Hadamard's work in studying the trajectories of point masses on a surface led to certain non-linear differential equations whose solution also gave properties of geodesics.
• Matrices whose determinants satisfied equality in the relation are today called Hadamard matrices and are important in the theory of integral equations, coding theory and other areas.
• In particular he worked on the partial differential equations of mathematical physics producing results of outstanding importance.
• He continued to produce books and papers of the highest quality, publishing perhaps his most famous text Lectures on Cauchy's problem in linear partial differential equations in 1922.

449. Henry Fine (1858-1928)
• Two further paper On the functions defined by differential equations with an extension of the Puiseux polygon construction to these equations, and Singular solutions of ordinary differential equations appeared in 1889 and 1890 respectively.
• He gave his retiring address as president on An unpublished theorem of Kronecker respecting numerical equations.

450. Eustachy yliski (1889-1954)
• Can you tell me what is the Schrodinger equation?" I said: "I don't know," and then he said: "All right.
• The Schrodinger equation is the fundamental equation of (non-relativistic) quantum mechanics, which was not part of the syllabus, and I am quite sure that Żyliński himself didn't know the Schrodinger equation.

451. Elena Moldovan Popoviciu (1924-2009)
• For many years she directed the Seminar "Tiberiu Popoviciu" on Functional Equations, Approximation and Convexity.
• Elena Popoviciu was also very much involved in the editorial work of the following journals: Revue d'Analyse Numerique et de Theorie de l'Approximation and Annals of the Tiberiu Popoviciu Seminar of Functional Equations, Approximation and Convexity.
• The topics of the conference were analysis, functional equations, approximation and convexity.
• Wolfgang Breckner contributed the biographical article [',' W W Breckner, Professor Elena Popoviciu is 75 (Romanian), in L Lupsa and M Ivan, Analysis, functional equations, approximation and convexity.

452. Elias Stein (1931-)
• He was among the first to appreciate the interplay among partial differential equations, classical Fourier analysis, several complex variables and representation theory.
• For more than a century there has been a significant and fruitful interaction between Fourier analysis, complex function theory, partial differential equations, real analysis, as well as ideas from other disciplines such as geometry and analytic number theory, etc.
• Stein's fusion of complex analysis, partial differential equations, analysis on nilpotent Lie groups, and Euclidean harmonic analysis has deeply influenced countless mathematicians.
• Stein is one of the foremost experts in harmonic analysis in the world, and he has made stellar contributions to this field as well as related fields such as the theory of several complex variables and partial differential equations.

453. William Edge (1904-1997)
• The equation of the scroll of tangents of the common curve of two quadrics is due to Cayley in 1850.
• Salmon, in his famous text, gave an equation in covariant form.
• Edge gave a procedure for finding this equation in 1979.
• Bring's curve was first studied in Klein's 1884 book in connection with the transformation to reduce the general quintic equation to the form x5 + ex + f = 0.

454. Sergei Alekseevich Chaplygin (1869-1942)
• His paper On the motion of a heavy body of revolution in a horizontal plane (1897) was the first to present the general equation of motion of a nonholonomic system.
• This equation is a generalisation of Lagrange's equation.
• He had developed methods of approximation for solving differential equation and he presented his first results on that topic to the Moscow Mathematical Society in 1905.

455. Igor Kluvánek (1931-1993)
• The book, covered Differential and Integral calculus, Analytic geometry, Differential equations and Complex variable [',' M Trenkler, Predhovor, in S Tkacik, J Guncaga, P Valihora and M Gerec (eds.), Igor Kluvanek: Prispevky zo seminara venovaneho nedozitym 75.
• This is a monograph on the geometry of the range of a vector measure and applications to control systems governed by partial differential equations.
• Moreover, it opens the new area of applications of vector measures to control systems governed by partial differential equations.
• The subject matter of the monograph under review is motivated by the fact that in describing superpositions of evolution processes one often encounters serious problems in solving the corresponding evolution equations.

456. Tomás Rodríguez Bachiller (1899-1980)
• In May 1923 Bachiller applied to the Junta para la Ampliacion de Estudios (now the Consejo Superior de Investigaciones Cientificas) for a one-year scholarship in order to study the theory of functions and differential equations in Germany and Switzerland.
• In particular he attended Emile Borel's course on elasticity, Jules Drach's course on contact transformations, Emile Picard's course on algebraic curves and surfaces, Elie Cartan's course on fluid mechanics, Jacques Hadamard's course on differential equations, the course that Claude Guichard (1861-1924) delivered on differential geometry and Laplace transformations, Henri Lebesgue's course on topology and Ernest Vessiot's courses on partial differential equations and on group theory.
• In October 1932 Bachiller's became an acting professor when the chair of differential equations became vacant.

457. Giovanni Prodi (1925-2010)
• He graduated from the University of Parma on 24 November 1948 having submitted his thesis on problems of stability in the theory of differential equations.
• He published papers on differential equations during this period which were directly related to his thesis: Un'osservazione sugl'integrali dell'equazione y" + A(x)y = 0 nel caso A(x) → +∞ per x → ∞ Ⓣ (1950); Nuovi criteri di stabilita per l'equazione y" + A(x)y = 0.
• It was while he was in Trieste that Prodi produced the most famous of his research results when he proved important uniqueness theorems for two-dimensional Navier-Stokes equations.
• This book was in the line of the work of Renato Caccioppoli and like the pioneering monograph 'Problemi di esistenza in analisi funzionale' Ⓣ of Carlo Miranda [',' La figura di Giovanni Prodi nella didattica della matematica.','1949], it put the emphasis upon the application of global implicit function theorems to the existence and multiplicity of solutions of nonlinear elliptic partial differential equations.

458. Stanislaw Golab (1902-1980)
• Professor Golab dealt with different fields of mathematics such as geometry, topology, algebra, analysis, logic, functional and differential equations, the theory of numerical methods and various applications of mathematics.
• In [',' K Kuczma, Activity of Professor Stanislaw Golab in the theory of functional equations, Collection of articles dedicated to Stanislaw Golab on his 70th birthday I, Demonstratio Math.
• may be considered as the father figure of the Polish school of functional equations.
• All Polish mathematicians working in the theory of functional equations are - directly or indirectly - pupils of Professor Golab.

• He was given a topic in the theory of differential equations by George Birkhoff but he began reading books on logic which seemed to him far more interesting that his research topic.
• Curry now made his final change in direction and decided to give up his doctoral studies on differential equations and to write a doctoral dissertation on logic.
• this advantage, of course, implies a restriction on the scope of the treatment, because it is limited to the rational aspects such as arise from ordinary linear differential equations with constant coefficients.
• For the more general cases of partial differential equations, fractional operators, etc., the theory of integral transforms is doubtless unavoidable.

460. Gregorio Ricci-Curbastro (1853-1925)
• In 1875 Ricci-Curbastro was awarded a doctorate for his thesis On Fuchs's research concerning linear differential equations.
• Three of these articles appeared in Nuovo Cimento in 1877 and, in the same year, an article appeared in Giornale di matematiche di Battaglini which Dini had asked him to write on Lagrange's problem on a system of linear differential equations.
• Ricci-Curbastro's early work was in mathematical physics, particularly on the laws of electric circuits and differential equations.
• In the paper, applications are given by Ricci-Curbastro and Levi-Civita to the classification of the quadratic forms of differentials and there are other analytic applications; they give applications to geometry including the theory of surfaces and groups of motions; and mechanical applications including dynamics and solutions to Lagrange's equations.

461. Otto Hesse (1811-1874)
• the special forms of linear equation and of planar equation that Hesse used in these books are called Hesse's normal form of the linear equation and of the planar equation in all modern textbooks on the discipline.

462. Joseph Fourier (1768-1830)
• Having left St Benoit in 1789, he visited Paris and read a paper on algebraic equations at the Academie Royale des Sciences.
• The second objection was made by Biot against Fourier's derivation of the equations of transfer of heat.
• the manner in which the author arrives at these equations is not exempt of difficulties and that his analysis to integrate them still leaves something to be desired on the score of generality and even rigour.
• If they had illuminated this branch of physics by important and general views and had greatly perfected the analysis of partial differential equations, if they had established a principal element of the theory of heat by fine experiments ..

463. Jan Mikusiski (1913-1987)
• thesis Sur un probleme d'interpolation pour les integrales des equations differentielles lineaires and, after defending it, was awarded the degree on 25 July 1945.
• Rudolf Hilfer, Yury Luchko and Zivorad Tomovski write in [',' R Hilfer, Y Luchko and Z Tomovski, Operational method for the solution of fractional differential equations with generalised Riemann-Liouville fractional derivatives, Fractional Calculus and Applied Analysis 12 (3) (2009), 299-318.','7]:- .
• The Mikusiński operational calculus was successfully used in ordinary differential equations, integral equations, partial differential equations and in the theory of special functions.

464. James Clerk Maxwell (1831-1879)
• Maxwell showed that a few relatively simple mathematical equations could express the behaviour of electric and magnetic fields and their interrelation.
• The four partial differential equations, now known as Maxwell's equations, first appeared in fully developed form in Electricity and Magnetism (1873).
• Plus Magazine (Maxwell's equations) .

465. Leopold Kronecker (1823-1891)
• students to hear that Kronecker was questioned at his oral on a wide range of topics including the theory of probability as applied to astronomical observations, the theory of definite integrals, series and differential equations, as well as on Greek, and the history of philosophy.
• The topics on which he lectured were very much related to his research: number theory, the theory of equations, the theory of determinants, and the theory of integrals.
• We have already indicated that Kronecker's primary contributions were in the theory of equations and higher algebra, with his major contributions in elliptic functions, the theory of algebraic equations, and the theory of algebraic numbers.

466. Kurt Friedrichs (1901-1982)
• He collaborated with Lewy on linear hyperbolic partial differential equations and they wrote a joint paper in 1927, and another joint paper, with Courant and Lewy, considered the stability of difference schemes for partial differential equations.
• He was now interested in operators on Hilbert spaces and applied these tools to initial value problem for hyperbolic equations.
• See [',' K O Friedrichs, von Neumann’s Hilbert space theory and partial differential equations, SIAM Rev.

467. Selig Brodetsky (1888-1954)
• The 5th International Congress for Applied Mechanics was held at Cambridge, Massachusetts, in 1938 and Brodetsky delivered a paper on the equations of motion of an airplane.
• Sections: Equations of motion, coefficients of statical and dynamical stability k, t; first approximation.
• Sections: Equations of motion, first approximation.
• Sections: Symmetrical aeroplane: equations of motion, first approximation.

468. Earle Raymond Hedrick (1876-1943)
• He was awarded a doctorate by Gottingen in February 1901 for a dissertation, supervised by Hilbert, Uber den analytischen Charakter der Losungen von Differentialgleichungen (On the analytic character of solutions of differential equations).
• This strengthen his interests in differential equations, the calculus of variations, and functions of a real variable which he would work on for the rest of his life.
• The second of these two papers is the two-part paper On the characteristics of differential equations both parts of which appeared in the Annals of Mathematics in 1903.
• The importance of the theory of characteristics in the study of differential equations is well known to all who are interested in that subject.

469. Roger Penrose (1931-)
• In this paper Penrose defined a generalized inverse X of a complex rectangular (or possibly square and singular) matrix A to be the unique solution to the equations AXA = A, XAX = X, (AX)T = AX, (XA)T = XA.
• He used this generalized inverse for problems such as solving systems of matrix equations, and finding a new type of spectral decomposition.
• In the following year Penrose published On best approximation solutions of linear matrix equations which used the generalized inverse of a matrix to find the best approximate solution X to AX = B where A is rectangular and non-square or square and singular.
• His development of Twistor Theory has produced a beautiful and productive approach to the classical equations of mathematical physics.

• his study of the theory of linear integral equations.
• Measure and integral, Banach and Hilbert space, linear integral equations (1953) which contained much of his own research as well as material from a lecture course by N G de Bruijn.
• Its main feature is the emphasis laid on integral equations and especially on those with symmetrizable kernel, a domain of research in which we owe to the author many personal results.
• Measure and integral, Banach and Hilbert space, linear integral equations (1953), we have already mentioned above.

471. Carl Jacobi (1804-1851)
• By the time Jacobi left school he had read advanced mathematics texts such as Euler's Introductio in analysin infinitorum Ⓣ and had been undertaking research on his own attempting to solve quintic equations by radicals.
• Kummer had made advances beyond what Jacobi had achieved on third-order differential equations and Jacobi wrote to his brother Moritz in 1836 describing how Kummer had managed to solve problems which had defeated him.
• Jacobi carried out important research in partial differential equations of the first order and applied them to the differential equations of dynamics.

472. John von Neumann (1903-1957)
• He was notorious for dashing out equations on a small portion of the available blackboard and erasing expressions before students could copy them.
• It was then that he became aware of the mysteries underlying the subject of non-linear partial differential equations.
• His work, from the beginnings of the Second World War, concerns a study of the equations of hydrodynamics and the theory of shocks.
• The phenomena described by these non-linear equations are baffling analytically and defy even qualitative insight by present methods.

473. Oliver Byrne (1810-1880)
• Daniel J Cohen writes in [',' D J Cohen, The creed of St Athanasius proved by a mathematical parallel, in Equations from God: Pure Mathematics and Victorian Faith (John Hopkins University Press, Baltimore, 2007), 73.','8]:- .
• Byrne then erected two vertical columns: the left containing the English Book of Common Prayer translation of the Quicunque Vult (the traditional description of the Athanasian Creed), the right containing parallel mathematical equations involving infinity that purported to establish the truth of the statements on the left.
• His books The Essential Elements of Practical Mechanics, based on the principle of work; designed for engineering students (1867) and General Method of Solving Equations of all degrees; applied particularly to equations of the second, third, fourth, and fifth degrees (1868) were both published by E & F N Spon.

474. William Horner (1786-1837)
• Horner is largely remembered only for the method, Horner's method, of solving algebraic equations ascribed to him by Augustus De Morgan and others.
• This discussion is somewhat moot because the method was anticipated in 19th century Europe by Paolo Ruffini (it won him the gold medal offered by the Italian Mathematical Society for Science who sought improved methods for numerical solutions to equations), but had, in any case, been considered by Zhu Shijie in China in the thirteenth century.
• Horner made other mathematical contributions, however, publishing a series of papers on transforming and solving algebraic equations, and he also applied similar techniques to functional equations.

475. George Birkhoff (1884-1944)
• Birkhoff read Poincare's works on differential equations and celestial mechanics and he learnt more, and was more strongly influenced in the direction his research was taking, by Poincare than from his supervisor.
• The doctoral thesis which Birkhoff submitted was entitled Asymptotic Properties of Certain Ordinary Differential Equations with Applications to Boundary Value and Expansion Problems and it led to the award of his Ph.D.
• Birkhoff's work on linear differential equations, difference equations and the generalised Riemann problem mostly all arose from the basis he laid in his thesis.

476. Joseph Liouville (1809-1882)
• This he did in October of 1830 but even at this stage he had written a number of papers which he had submitted to the Paris Academy on electrodynamics, partial differential equations and the theory of heat.
• His work on boundary value problems on differential equations is remembered because of what is called today Sturm-Liouville theory which is used in solving integral equations.
• Sturm and Liouville examined general linear second order differential equations and examined properties of their eigenvalues, the behaviour of the eigenfunctions and the series expansion of arbitrary functions in terms of these eigenfunctions.

477. Jules Drach (1871-1949)
• Drach viewed Emile Picard's application, in 1887, of Galois theory to linear differential equations as a model of perfection and he tried to extend Galois theory to differential equations in general, building on the work of Lie and Vessiot in addition to that of Emile Picard.
• Other papers by Drach include three published in 1908: Sur les systemes completement orthogonaux de l'espace euclidien a n dimensions Ⓣ; Recherches sur certaines deformations remarquables a reseau conjugue persistant Ⓣ; and Sur le probleme logique de l'integration des equations differentielles Ⓣ.
• After the war ended he published his geometric approach to such problems in L'equation differentielle de la balistique exterieure et son integration par quadratures Ⓣ (1920).
• Drach's results can be compared with the modern treatment of the same class of equations.
• Another example of his work is Sur la theorie des corps plastiques et l'equation d'Airy-Tresca Ⓣ which he published in 1946.
• Around the same time Drach published two papers on partial differential equations: Sur les equations aux derivees partielles du premier ordre dont les caracteristiques sont lignes asymptotiques des surfaces integrales Ⓣ (1947); and Sur des equations aux derivees partielles du premier et du second ordre dont les caracteristiques sont lignes asymptotiques des surfaces integrales Ⓣ (1948).

478. Joseph Ritt (1893-1951)
• Ritt resigned his position at the Naval Observatory and began working for his doctorate which was awarded in 1917 for his thesis On a general class of linear homogeneous differential equations of infinite order with constant coefficients.
• Ritt had begun a new major research topic in the 1930s when he began to create a theory of ordinary and partial differential equations.
• The first book was Differential equations from an algebraic standpoint (1932) and the second, a very major revision and extension of the first, was Differential Algebra (1950).
• In the last three years of his life Ritt began a deep study of the applications of Lie theory to homogeneous differential equations.

479. Alexander von Brill (1842-1935)
• It is curious to note that the example chosen of non-holonomous systems, in which the constraints are expressible by a differential equation unintegrable per se, is as simply dealt with by direct application of Newton's second law, which avoids what Professor Brill terms the "delicate considerations and special precautions" necessary in applying Lagrange's equations.

480. Giulio Vivanti (1859-1949)
• Prof Giulio Vivanti, in addition to the service provided in this Royal University, as Internal Professor of the normal school, mathematical section, annexed to the Faculty of Science, and in addition to acting as substitute in algebraic analysis and analytical geometry that he did during the last year during the illness of Prof G Platner, he also held a free course on 'The theory of the algebraic resolution of equations' a course approved by the Faculty of Science [..
• The works on the application of the function can also be noted in the Poncelet polygons, on the surfaces of constant mean curvature, icosahedral irrationality, contact transformations, the theory of partial derivatives of the 2nd order, the extension of the Ampere method, on the integral polydromes of differential equations, and not a few others.
• The clearest testimony to his teaching skills lies in his nineteen university and six secondary school textbooks, together with the clearly-explained booklets published by Hoepli on analytic functions, on integral equations, and on polyhedric and modular functions, some of which were translated into German and favourably received in Italy and abroad.

481. Wen-Tsun Wu (1919-2017)
• He based his method on the idea of a characteristic set which had been introduced by Joseph Ritt in his algebraic and algorithmic approach to differential equations.
• It is in Chapter 4 that Wu explains how to translate geometrical problems into polynomial equations.
• In 2000 Wu published Mathematics mechanization : Mechanical geometry theorem-proving, mechanical geometry problem-solving and polynomial equations-solving.

482. Donald Pack (1920-2016)
• These include The development of bivariational principles for the calculation of upper and lower bounds (1983), Upper and lower bounds of bilinear functionals in nonlinear problems (1984), Complementary bounds for inner products associated with nonlinear equations (1984), Optimal bounds for bilinear forms associated with linear equations (1985), Approximation to inverses of normal operators (1986) and Application of the superconvergence properties of the Galerkin approximation to the calculation of upper and lower bounds for linear functionals of solutions of integral equations (1987).

483. William Clifford (1845-1879)
• On a rough trial the other day, the intrinsic equation seemed not very difficult to obtain; if I get at any result, I will send it you to-morrow.
• I have been trying to construct a second interpretation of mechanical equations, similar to that of tangential coordinates, but have failed hitherto.

484. Giusto Bellavitis (1803-1880)
• enables us to express by means of formulae the results of geometric constructions, to represent geometric propositions by means of equations, and to replace a logical argument by the transformation of equations.
• In algebra he continued Ruffini's work on the numerical solution of algebraic equations and he also worked on number theory.

485. Jean d'Alembert (1717-1783)
• He was a pioneer in the study of partial differential equations and he pioneered their use in physics.
• The article contains the first appearance of the wave equation in print but again suffers from the defect that he used mathematically pleasing simplifications of certain boundary conditions which led to results which were at odds with observation.

486. Percy Daniell (1889-1946)
• Among the courses that Hilbert was giving at this time were Partial Differential Equations, Mathematical Foundations of Physics, and Theory of the Electron.
• presents one of the earliest mathematical treatments of continuous time Markov processes, including the Chapman-Kolmogorov equation (ten years before Kolmogorov) and a short treatment of the Wiener process (two years before Wiener).

487. Georg Frobenius (1849-1917)
• On the algebraic solution of equations, whose coefficients are rational functions of one variable.
• The theory of linear differential equations.
• In his work in group theory, Frobenius combined results from the theory of algebraic equations, geometry, and number theory, which led him to the study of abstract groups.

488. George FitzGerald (1851-1901)
• This was Electricity and Magnetism by Maxwell which, for the first time, contained the four partial differential equations, now known as Maxwell's equations.
• His first work On the equations of equilibrium of an elastic surface filled in cases of a problem studied by Lagrange.

489. Charles Fefferman (1949-)
• His work on partial differential equations, Fourier analysis, in particular convergence, multipliers, divergence, singular integrals and Hardy spaces earned him a Fields Medal at the International Congress of Mathematicians at Helsinki in 1978.
• Professor Charles Fefferman's contributions and ideas have had an impact on the development of modern analysis, differential equations, mathematical physics and geometry, with his most recent work including his sharp (computable) solution of the Whitney extension problem.
• He has also made major contributions through his editorial work being on the editorial boards of: Communications in Partial Differential Equations; Advances in Mathematics; Revista Mat.

490. Carl Runge (1856-1927)
• Runge then worked on a procedure for the numerical solution of algebraic equations in which the roots were expressed as infinite series of rational functions of the coefficients.
• There were three standard methods for the numerical solution of such equations, namely by Newton, Bernoulli and Graffe, and the method found by Runge had all three of the standard methods as special cases.
• He worked out many numerical and graphical methods, gave numerical solutions of differential equations, etc.

491. Wallace J Eckert (1902-1971)
• The first is the development of the theory or the solution of the differential equations of motion expressing the coordinates of the moon as explicit functions of time.
• In order to bring the Tables within even their present length, various parts of the basic equations were curtailed whenever permissible in the light of observational requirements (as then visualised).
• Eckert therefore decided not to recompute new tables but to compute the ephemerides directly from Brown's equations.

492. Bernhard Riemann (1826-1866)
• In October he set to work on his lectures on partial differential equations.
• Riemann studied the convergence of the series representation of the zeta function and found a functional equation for the zeta function.

493. Charles Fox (1897-1977)
• He submitted two further papers in June 1925, The Expression of Hypergeometric Series in Terms of Similar Series, and Some Further Contributions to the Theory of Null Series and Their Connexion with Null Integrals to the same Proceedings; both were published in 1927 as was his next paper A Generalization of an Integral Equation Due to Bateman which he submitted in 1926.
• Fox's main contributions were on hypergeometric functions, integral transforms, integral equations, the theory of statistical distributions, and the mathematics of navigation.

494. Henri Brocard (1845-1922)
• The text consists of brief descriptive paragraphs, with diagrams and equations of these curves.
• In 1876, Brocard asked if the only solutions to the equation n! + 1 = m2, in positive integers (n, m), are (4, 5), (5, 11), (7, 71).

495. Brian Haselgrove (1926-1964)
• The problem of stellar evolution is expressed, mathematically, by a set of non-linear partial differential equations describing the variation of density and temperature as a function of time and of distance from the star centre.
• In The solution of non-linear equations and of differential equations with two-point boundary conditions (1961) Haselgrove suggests general iterative techniques, based on an n-dimensional extension of the Newton-Raphson process.

496. George E Andrews (1938-)
• Andrews had published three papers by the time he had completed his thesis work: An asymptotic expression for the number of solutions of a general class of Diophantine equations (1961); A lower bound for the volume of strictly convex bodies with many boundary lattice points (1963); and On estimates in number theory (1963).
• This last paper, in the American Mathematical Monthly, gave a method for finding an upper bound for the number of solutions of a Diophantine equation of the form y = f (x).

497. Andrei Andreyevich Markov (1856-1922)
• He wrote his first mathematics paper while at the Gymnasium but his results on integration of linear differential equations which were presented in the paper were not new.
• Markov graduated in 1878 having won the gold medal for submitting the best essay for the prize topic set by the faculty in that year - On the integration of differential equations by means of continued fractions.
• During his lectures he did not bother about the order of equations on the blackboard, nor about his personal appearance.

498. Daniel Quillen (1940-2011)
• for his thesis on partial differential equations entitled Formal Properties of Over-Determined Systems of Linear Partial Differential Equations.
• He was an invited plenary speaker at the British Mathematical Colloquium in Aberdeen in 1983 when he gave the lecture Infinite determinants over algebraic curves arising from problems in geometry, differential equations and number theory.

• He also discussed integer solutions of first degree indeterminate equation by a method called kuttaka.
• An example of a problem given in the Ganita Sara Samgraha Ⓣ which leads to indeterminate linear equations is the following: .

500. Hermann Laurent (1841-1908)
• He wrote 30 books and a fair number of papers on infinite series, equations, differential equations and geometry.
• The last three volumes are devoted entirely to the solution and application of ordinary and partial differential equations.

501. Ward Cheney (1929-2016)
• Note on a paper by Zuhovickii concerning the Tchebycheff problem for linear equations (1958) appeared first as a 'Convair Astronautics Mathematical Pre-print' in 1957 and then was published in the SIAM Journal in 1958.
• The next paper A finite algorithm for the solution of consistent linear equations and inequalities and for the Tchebycheff approximation of inconsistent linear equations (1958) is introduced by the authors as follows:- .

502. Otto Hölder (1859-1937)
• Klein's lectures on Galois theory at Gottingen had interested Holder who began to study the Galois theory of equations and from there he was led to study composition series of groups.
• Holder was one of the first to give a rigorous account of the famous classical case where a splitting field is not a radical extension: the irreducible cubic equation over the rationals with three real roots, where it is nonetheless necessary to adjoin complex roots of unity.

503. Pierre de Carcavi (1600-1684)
• (2) The equation x3 + y3 = z3 has no solutions in integers.
• (3) The equation y2 + 2 = x3 admits no solutions in integers except x = 3, y = 5.
• (4) The equation y2 + 4 = x3 admits no solutions in integers except x = 2, y = 2 and x = 5, y = 11.

504. Simon Donaldson (1957-)
• Moreover the methods are new and extremely subtle, using difficult nonlinear partial differential equations.
• His methods have been described as extremely subtle, using difficult nonlinear partial differential equations.
• Using instantons, solutions to the equations of Yang-Mills gauge theory, he gained important insight into the structure of closed four-manifolds.

505. Juan de Ortega (1480-1568)
• In the second part of the book, devoted mostly to geometry, Ortega gives a method of extracting square roots very accurately using Pell's equation, which is surprising since a general solution to Pell's equation does not appear to have been found before Fermat over 100 years later.
• Pell's equation .

506. Anatolii Asirovich Goldberg (1930-2008)
• Several other mathematicians at the university were equally important for Goldberg's development, including Boris Vladimirovich Gnedenko, Yaroslav Borisovich Lopatynsky, who held the chair of differential equations, and Lev Israelevich Volkovyskii who had been a student of Mikhail Alekseevich Lavrent'ev and was working on complex analysis, particularly quasiconformal mappings and Riemann surfaces.
• Goldberg was asked to give the opening memorial plenary lecture on memorial meeting in honour of Shlomo Strelitz at the 'Conference of Differential Equations and Complex Analysis' at the University of Haifa in December 2000.
• He gave the lecture On the growth of entire solutions of algebraic differential equations which was published in 2005.

507. Johannes Boersma (1937-2004)
• The discussion centres around the use of integral representation theory to reduce such problems to Fredholm integral equations which are suitable for the study of low frequency oscillations.
• The results of the airfoil analysis are infinite systems of linear equations, from which numerical results can be obtained by truncation.
• Complex Function Theory, Applied Analysis and Partial Differential Equations which provided the interesting combination of mathematical theory applied to physics problems.

508. Kathleen McNulty Antonelli (1921-2006)
• However the war had ended before the machine came into service but it was still used for the numerical solution of differential equations as intended.
• Petzinger, in [',' T Petzinger, History of software begins with the work of some brainy women, Wall Street Journal (November 1996).','3], describes the way that McNulty used ENIAC to solve differential equations after the construction of the machine was complete in February 1946:- .
• The first task was breaking down complex differential equations into the smallest possible steps.

509. Cecilia Payne-Gaposchkin (1900-1979)
• Geometry and algebra were part of our studies and I delighted especially in the solution of quadratic equations.
• But I remember his saying to me after some months [of applying the ionization equation to spectra], "Why don't you get some little thing together and publish it?" And I said, "I don't want to do that, I should regard that as a confession of failure, I want to get this whole thing together." What really inspired me was the announcement which I had heard before I left Cambridge, England, on the subject of the Adams Prize for the following year - the subject was the study of matter at high temperatures.

510. Christian Juel (1855-1935)
• Many readers must have felt that if all that projective geometry could tell us of a problem involving a cubic equation was that it has at least one solution, and not more than three, then projective geometry had not by any means justified its claims to replace the ordinary algebraic kind.
• The main topics covered are problems leading to cubic and quartic equations in one variable, reduced to finding the intersections of two conics, of which in the first case one intersection is known; the two-dimensional chain, and its relations; anti-collineations; the projective metric, Euclidean and non-Euclidean; the quadratic transformation, the rational plane cubic, and the general plane cubic.

511. Ernest Wilczynski (1876-1932)
• By that time he had published over a dozen papers in astronomy, but his interests moved towards differential equations which arose in his study of the dynamics of astronomical objects.
• From there his interests became pure mathematical interests in differential equations.
• But Wilczynski was the first ever to appreciate, demonstrate and exploit the utility of completely integrable systems of linear homogeneous differential equations for projective differential geometry.

512. Élie Cartan (1869-1951)
• Cartan worked on continuous groups, Lie algebras, differential equations and geometry.
• Cartan's papers on differential equations are in many ways his most impressive work.
• Cartan is certainly one of the greatest and most original minds of mathematics, whose work on Lie groups, differential geometry, and the geometric theory of differential equations is at the foundation of much of what we do today.

513. al-Kashi (1390-1450)
• He also considered the equation associated with the problem of trisecting an angle, namely a cubic equation.
• He was not the first to look at approximate solutions to this equation since al-Biruni had worked on it earlier.

• During this year he published five papers: Microscopic Theory of the Einstein optical scattering equations (1968) was co-authored with R K Bullough, B V Thompson (also from the Department of Mathematics at UMIST) and F Hynne (from the H C Orsted Institutet in Copenhagen); and the four papers Optical propagators and properties of the finite molecular crystal (1969), Dielectric constants for the cubic molecular crystal (1969), The binding energy of molecular crystals (1969) and Longitudinal modes and optical rotation in the finite molecular crystal (1969) which were all 2-author works by Obada and Bullough.
• The conference was held in Dar al-Diyafa, Ain Shams University, Cairo and covered the following topics: Mathematical Physics, Computer Science, Numerical Analysis Methods and Applications, Topology & Geometry and Applications, Algebra and applications, Differential Equation and Applications, Dynamical Systems and Applications, Mathematical Statistics, and Functional Analysis.

515. Ferdinand Joachimsthal (1818-1861)
• This work, which studied the integrability of differential equations with more than two variables, gave a complete answer to a question that had been considered by Lagrange.
• Joachimsthal introduced a notation that can be used to write down the equations of tangents and polars of plane and projective conics.
• The various notations introduced by Joachimsthal in the area of second order equations and conic sections have an influence that has extended far beyond these areas, for example into the important work of Frank Morley.

• He gives propositions determining the centre of curvature which lead immediately to the Cartesian equation of the evolute.
• Included in it are a series of propositions which, though worked out by the purest geometrical methods, actually lead immediately to the determination of the evolute of each of the three conics; that is to say, the Cartesian equations of the evolutes can be easily deduced from the results obtained by Apollonius.

• He did this by using an indeterminate equation of the second order, Nx2 + 1 = y2, where N is the number whose square root is to be calculated.
• If x and y are a pair of roots of this equation with x < y then √N is approximately equal to y/x.
• History Topics: Pell's equation .

518. André Bloch (1893-1948)
• While other patients constantly requested that they be given their freedom, he was perfectly happy to study his equations and keep his correspondence up to date.
• Bloch worked on a large range of mathematical topics; for example, function theory, geometry, number theory, algebraic equations and kinematics.
• He published articles such as: Sur les integrales de Fresnel Ⓣ (1919), Memoire d'analyse diophantienne lineaire Ⓣ (1922), Les proprietes diametrales des coniques deduites de la definition focale Ⓣ (1924), Les theoremes de M Valiron sur les fonctions entieres et la theorie de l'uniformisation Ⓣ (1925), Les fonctions holomorphes et meromorphes dans le cercle-unite Ⓣ (1926), Le probleme de la cubique lacunaire Ⓣ (1927), and Racines multiples des systemes de m equations a m inconnues Ⓣ (1927).
• He wrote two papers in collaboration with Polya, namely On the roots of certain algebraic equations (1932), and Abschatzung des Betrages einer Determinante Ⓣ (1933).

519. Francis Upton (1852-1921)
• Whatever he did and worked on was executed in a purely mathematical manner and any Wrangler at Cambridge would have been delighted to see him juggle with integral and differential equations with a dexterity that was surprising.
• He drew the shape of the bulb exactly on paper, and got the equation of its lines with which he was going to calculate its contents, when Mr Edison again appeared and asked him what it was.

520. George Boole (1815-1864)
• Boole had begun to correspond with De Morgan in 1842 and when in the following year he wrote a paper On a general method of analysis applying algebraic methods to the solution of differential equations he sent it to De Morgan for comments.
• Boole also worked on differential equations, the influential Treatise on Differential Equations appeared in 1859, the calculus of finite differences, Treatise on the Calculus of Finite Differences (1860), and general methods in probability.

521. Tjalling Charles Koopmans (1910-1985)
• He showed that the desired result is obtainable by the straightforward solution of a system of equations involving the costs of the materials at their sources and the costs of shipping them by alternative routes.
• He also devised a general mathematical model of the problem that led to the necessary equations.
• In Identification problems in economic model construction (1949) he used matrix methods to study structural equations within a linear economic model.

522. Henry Ernest Dudeney (1857-1930)
• Other puzzles simply reduced to systems of linear equations if a mathematical solution was sought.
• Problem 11 from the same book reduces to a quadratic equation:- .

523. Georg Cantor (1845-1918)
• the numbers which are roots of polynomial equations with integer coefficients, were countable.
• A transcendental number is an irrational number that is not a root of any polynomial equation with integer coefficients.

524. Mikhail Egorovich Vashchenko-Zakharchenko (1825-1912)
• After his studies in Kazan, he returned to Kiev and he taught at Kiev Cadet School from 1855 to 1862, receiving his Master's Degree in 1862 for a dissertation on the operational method and its application to solving linear differential equations.
• In particular he worked on the theory of linear differential equations, the theory of probability (see [',' R A Sapsai, The work of Mikhail Egorovich Vashchenko-Zakharchenko in the field of probability theory (Russian), in A N Bogolyubov (ed.), On the history of the mathematical sciences 167 ’Naukova Dumka’ (Kiev, 1984), 36-39.','3]) and non-euclidean geometry.
• He published The Symbolic Calculus and its Application to the Integration of Linear Differential Equations in 1862.

• It is a text which covers the standard mathematical methods of Aryabhata I such as the solution of the indeterminate equation by = ax ± c (a, b, c integers) in integers which is then applied to astronomical problems.
• The paper [',' P K Majumdar, A rationale of Bhatta Govinda’s method for solving the equation ax - c = by and a comparative study of the determination of ’Mati’ as given by Bhaskara I and Bhatta Govinda, Indian J.
• The reader who is wondering what the determination of "mati" means in the title of the paper [',' P K Majumdar, A rationale of Bhatta Govinda’s method for solving the equation ax - c = by and a comparative study of the determination of ’Mati’ as given by Bhaskara I and Bhatta Govinda, Indian J.

526. Hubert Wall (1902-1971)
• In anticipation of Hellinger's arrival, Wall started studying differential equations from Hellinger's point of view (which was similar to the point of view of Hilbert and Courant).
• As a result, Wall later wrote 'Creative Mathematics' very much in the modern spirit of differential equations in which existence, uniqueness, qualitative study, and numerical computation are emphasized over 'closed form' solutions.
• A fourth area was the area of Harmonic Matrices and the continued fraction integral (or continuous continued fraction), and in this he reworked and generalized results that correspond to the differential analogue of the linear equations that go into the Jacobi matrix.

527. Jack Todd (1911-2007)
• Solution of differential equations by recurrence relations (1950); Experiments on the inversion of a 16 × 16 matrix (1953); Experiments in the solution of differential equations by Monte Carlo methods (1954); The condition of the finite segments of the Hilbert matrix (1954); Motivation for working in numerical analysis (1954); and A direct approach to the problem of stability in the numerical solution of partial differential equations (1956).

528. Lee Segel (1932-2005)
• The first publications by Segel were Application of conformal mapping to viscous flow between moving circular cylinders (1960), A uniformly-valid asymptotic expansion of the solution to an unsteady boundary-layer problem (1960), and Application of conformal mapping to boundary perturbation problems for the membrane equation (1961).
• This textbook introduces differential equations, biological applications, and simulations and emphasises molecular events (biochemistry and enzyme kinetics), excitable systems (neural signals), and small protein and genetic circuits.

529. Norman Ferrers (1829-1903)
• They range over such subjects as quadriplanar co-ordinates, Lagrange's equations and hydrodynamics.
• In 1853 Sylvester published On Mr Cayley's impromptu demonstration of the rule for determining at sight the degree of any symmetrical function of the roots of an equation expressed in terms of the coefficients in the Philosophical Magazine.

530. Arnold Sommerfeld (1868-1951)
• In this thesis he studied the representation of arbitrary functions by the eigenfunctions of partial differential equations and other given sets of functions.
• His work on this topic contains important theory of partial differential equations.
• He lectured on a wide range of topics, giving lectures on probability and also on the partial differential equations of physics.

• Orr is best remembered today by applied mathematicians through the Orr-Sommerfeld equation that is an eigenvalue problem which models 2-dimensional modes of disturbance in a parallel shear flow.
• In the fourth edition [published in 1916] of 'Hydrodynamics', however, Lamb acknowledged that the stability equation for plane Couette flow was given by Orr, and afterwards independently by Sommerfeld.
• He was heard to say that research in the College of Science consisted of solving a quadratic equation which had not been solved before.

532. Georges Valiron (1884-1955)
• Among the papers that Valiron published in the years following World War I, we mention: Les theoremes generaux de M Borel dans la theorie des fonctions entieres Ⓣ (1920); Recherches sur le theoreme de M Picard Ⓣ (1921); Recherches sur le theoreme de M Picard dans la theorie des fonctions entieres Ⓣ (1922); Sur les fonctions entieres verifiant une classe d'equations differentielles Ⓣ (1923); Sur l'abscisse de convergence des series de Dirichlet Ⓣ (1924); Sur les surfaces qui admettent un plan tangent en chaque point Ⓣ (1926); and Sur la distribution des valeurs des fonctions meromorphes Ⓣ (1926).
• The second volume, published in 1945, was entitled Equations Fonctionnelles; ApplicationsⓉ>.
• It covers ordinary differential equations, partial differential equations, and algebraic equations of two variables.

533. Augustin-Louis Cauchy (1789-1857)
• He did important work on differential equations and applications to mathematical physics.
• Numerous terms in mathematics bear Cauchy's name:- the Cauchy integral theorem, in the theory of complex functions, the Cauchy-Kovalevskaya existence theorem for the solution of partial differential equations, the Cauchy-Riemann equations and Cauchy sequences.

534. Thomas Simpson (1710-1761)
• By way of compensation, however, the Newton-Raphson method for solving the equation f (x) = 0 is, in its present form, due to Simpson.
• Newton described an algebraic process for solving polynomial equations which Raphson later improved.

535. Richard Varga (1928-)
• I took the chance and joined the staff at Bettis in June, 1954, immediately after getting my Ph.D., and it was a truly exciting experience for me! The problems to be solved on the computers were two- and three-dimensional multigroup diffusion equations, used to design nuclear reactors for submarines, and aircraft carriers, for example, as well as large land-based electric power generators.
• 'Matrix Iterative Analysis' belongs in the personal library of every numerical analyst interested in either the practical or theoretical aspects of the numerical solution of partial differential equations.
• The iterative procedures for solving finite-difference approximations to second-order partial differential equations of elliptic and parabolic types have been described in many places.

536. Louis Melville Milne-Thomson (1891-1974)
• In 1948 he published Applications of elliptic functions to wind tunnel interference while in 1957 he wrote a review paper A general solution of the equations of hydrodynamics which M G Scherberg reviews as follows:- .
• For example he wrote Consistency equations for the stresses in isotropic elastic and plastic materials (1942), and Stress in an infinite half-plane (1947).
• He gave two lectures in Madrid in 1951 on the elements of finite elasticity theory, the first lecture covering the topics of deformation tensors, stress, equations of motion, and energy.

537. Pietro Paoli (1759-1839)
• His research was on analytic geometry, calculus, partial derivatives, and differential equations.
• Although most mathematicians ignored Paolo Ruffini's proof of the impossibility of solving equations of degree greater than four by the method of radicals, Paoli read Ruffini's proof and wrote to him in 1799:- .
• and recommend greatly the most important theorem which excludes the possibility of solving equations of degree greater than four.

538. Antoni Zygmund (1900-1992)
• Among other topics, he worked on summability of numerical series, summability of general orthogonal series, trigonometric integrals, sets of uniqueness, summability of Fourier series, differentiability of functions, smooth functions, approximation theory, absolutely convergent Fourier series, multipliers and translation invariant operators, conjugate series and Taylor series, lacunary trigonometric series, series of independent random variables, random trigonometric series, the Littlewood-Paley, Luzin and Marcinkiewicz functions, boundary values of analytic and harmonic functions, singular integrals, partial differential equations and interpolation operators.
• Their famous joint papers over the next few years on singular integrals and partial differential equations, the most significant of which appeared in 1952, have had a major impact on modern analysis.
• For outstanding contributions to Fourier analysis and its applications to partial differential equations and other branches of analysis, and for his creation and leadership of the strongest school of analytical research in the contemporary mathematical world.

539. Archibald Milne (1875-1958)
• He read papers at meetings of the Society such as Notes on the equation of the parabolic cylinder on Friday 9 January 1914, The Conformal Representation of the Quotient of two Bessel Functions on 24 January 1916, and Note on the Peano-Baker method of solving linear differential equations on 11 February 1916.

540. Charles De la Vallée Poussin (1866-1962)
• Vallee Poussin's first mathematical research was on analysis, in particular concentrating on integrals and solutions of differential equations.
• One of his first papers in 1892 on differential equations was awarded a prize by the Belgium Academy.
• Volume 2 covered multiple integrals, differential equations, and differential geometry.

541. Fritz Noether (1884-1941)
• Ⓣ The thesis, which gives differential equations for the Bohr conditions, etc., was published in Annalen der Physik in the following year.
• Gottfried Emanuel Noether, Fritz Noether's younger son, writes in [',' G E Noether, Letter to the Editor, Integral Equations and Operator Theory 13 (2) (1990), 303-305.','8] about Sommerfeld's role in advising his father:- .
• In 1931 Noether presented a chapter on the investigation of the Navier-Stokes equations.

542. Mstislav Vsevolodovich Keldysh (1911-1978)
• Mstislav Keldysh, was also a very talented mathematician in the theory of functions of a complex variable and in differential equations.
• Examples of papers he published during this period illustrate the work he undertook at the Steklov Institute: Sur l'approximation en moyenne par polynomes des fonctions d'une variable complexe (1945), Sur l'interpolation des fonctions entieres (1947), On the characteristic values and characteristic functions of certain classes of non-self-adjoint equations (Russian) (1951), and On a Tauberian theorem (Russian) (1951).
• For instance a paper he published in 1951 on boundary value-problems for elliptic equations that degenerate on the boundary, that attracted much attention from Russian and foreign mathematicians had its origins in work he was doing in aerodynamics.

543. Laurent Schwartz (1915-2002)
• This theory provides a convenient formalism for many common situations in theoretical and applied analysis, but its greatest significance may be in connection with partial differential equations, particularly those of hyperbolic type, where its adaptability to local problems gives it an advantage over Hilbert space (and other primarily global) techniques.
• This has led to extensive studies of topological vector spaces beyond the familiar categories of Hilbert and Banach spaces, studies that, in turn, have provided useful new insights in some areas of analysis proper, such as partial differential equations or functions of several complex variables.
• I think every reader of his cited paper, like myself, will have left a considerable amount of pleasant excitement, on seeing the wonderful harmony of the whole structure of the calculus to which the theory leads and on understanding how essential an advance its application may mean to many parts of higher analysis, such as spectral theory, potential theory, and indeed the whole theory of linear partial differential equations ..

544. Enrico Fermi (1901-1954)
• He showed great talents, especially in mathematics and by the time he left elementary school at the age of ten he was puzzling out how the equation x2 + y2 = r2 represented a circle.
• In his essay Fermi derived the system of partial differential equations for a vibrating rod, then used Fourier analysis to solve them.

545. Ernst Meissel (1826-1895)
• Meissel's mathematical interests covered the following fields: number theory (in particular, properties of prime numbers), theta functions, elliptic functions, spherical trigonometry, hydrodynamics, ordinary differential equations, asymptotic expansions, and Bessel functions.
• a forerunner (in the theory of Bessel functions, in connection with Emden's equation etc.).

546. Platon Sergeevich Poretsky (1846-1907)
• the theoretical portion of [Poretsky's thesis] dealt with reducing the number of unknowns and equations for certain systems of cyclic equations that occur in practical astronomy.
• He published major works on methods of solution of logical equations, and on the reverse mode of mathematical logic.

547. Sewall Green Wright (1889-1988)
• Another paper by Wright which shows his mathematical approach to the subject is The differential equation of the distribution of gene frequencies which he published in 1945.
• He derives differential equations which are satisfied by the probability density function of the distribution of gene frequencies under certain conditions.

548. Hermann Arthur Jahn (1907-1979)
• The fundamental formulae are akin to those of classical perturbation theory, the corresponding formulae of which, for the special case of a Lagrange frequency equation, are given for convenience in the Appendix.
• In a different area he advocated the application of Morpurgo differential equations to nuclear physics problems many years before such a programme was developed in France and the U.S.S.R.

549. Gomes Teixeira (1851-1933)
• His performance had been outstanding and in 1871, while still an undergraduate, he wrote Desenvolvimento das funcoes em fraccao continua Ⓣ which showed how to develop functions as continued fractions and applied these techniques to approximate roots of equations using rapidly converging series.
• Among the papers he published in the following few years we mention several in French, namely Sur la decomposition des fractions rationnels Ⓣ (1877), Sur le nombre des fonctions arbitraires des integrales des equations aux derivees partielles Ⓣ (1878), Sur les derivees d'ordre quelconque Ⓣ (1880) and Sur les principes du calcul infinitesimal Ⓣ (1880).
• In the second volume of this journal, which appeared in 1880, Teixeira published a paper on the integration of second order linear partial differential equations and an obituary of Giusto Bellavitis.
• An orderly list of all the curves of every kind to which definite names have been assigned, accompanying each with a succinct exposition of its form, equations and general properties, and with a statement of the books in which, or the authors by whom, it was first made known.

• Thymaridas also gave methods for solving simultaneous linear equations which became known as the 'flower of Thymaridas'.
• For the n equations in n unknowns .
• He also shows how certain other types of equations can be put into this form.

551. Arnaud Denjoy (1884-1974)
• These great mathematicians gave Denjoy a strong background in complex function theory, continued fractions and differential equations and set him on the road to his great discoveries.
• In 1934 he wrote that his greatest achievements had been the integration of derivatives, the computation of the coefficients of a converging trigonometric series, a theorem on quasi-analytic functions, and differential equations on a torus.
• Choquet, very fairly, suggests that Denjoy's work on differential equations on a torus, not nearly so highly rated by Denjoy himself, is one of his most influential pieces of work and has [',' G Choquet, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1]:- .

552. Yulian Vasilievich Sokhotsky (1842-1927)
• His doctoral dissertation On definite integrals and functions with applications to expansion of series was an early investigation of the theory of singular integral equations.
• One of the first to approach problems of the theory of singular integral equations, Sokhotsky in this work considered important boundary properties of integrals of the type of Cauchy and, essentially, arrived at the so-called formulas of I Plemelj (1908).
• His work is important in the development of the theory of functions, in particular having applications in the theory of hypergeometric series and differential equations.

553. Alfred Clebsch (1833-1872)
• Pure mathematics became Clebsch's main research topic when he began to study the calculus of variations and partial differential equations.
• Clebsch, by taking as his starting-point an algebraic curve defined by its equation, made the theory more accessible to the mathematicians of his time, and added a more concrete interest to it by the geometrical theorems that he deduced from the theory of Abelian functions.

554. Nikolay Sonin (1849-1915)
• He continued working on his doctorate, essentially equivalent to the German habilitation, and after submitting a thesis on partial differential equations of the second order to the Moscow University he was awarded the degree in 1874.
• He has a sequence of polynomials named after him - the Sonin polynomials Tnm(x) satisfy the differential equation .

555. Elliott Montroll (1916-1983)
• He used both his expertise in chemistry and mathematics in his thesis Applications of the characteristic value theory of integral equations in which he applied integral equations to the study of imperfect gases.
• In the proceeding of the conference Nonlinear equations in abstract spaces held in 1977 at the University of Texas he published On some mathematical models of social phenomena in which he examined models for population growth and statistical models of other social phenomena.

556. Aleksei Vasilevich Pogorelov (1919-2002)
• He has solved a number of key problems in geometry in the large, in the foundations of geometry, and in the theory of the Monge-Ampere equations, and he also has obtained remarkable results in the geometric theory of stability of thin elastic shells.
• On Monge-Ampere equations of elliptic type (1960).
• This book presents a systematic exposition of a number of publications of A D Aleksandrov and his students, dealing with Monge-Ampere equations of elliptic type.

557. Mihailo Petrovi (1868-1943)
• He was already undertaking research for his doctorate advised by Charles Hermite and Emile Picard, and submitted his main thesis Sur les zeros et les infinis des integrales des equations differentielles algebriques Ⓣnin June 1894.
• of integrals of algebraic differential equations, and I apply the results found in the study of the integrals by placing myself in the point of view of the general theory of functions.
• In the 1890's he developed the hydraulic computer for the solution of first order ordinary differential equations.
• Called the hydraulic integrator, it was described in his paper Sur un procede d'integration graphique des equations differentielles Ⓣ published in Comptes rendus de l'Academie des Sciences de Paris in 1897.
• Petrović was asked to write Integration qualitative des equations differentielles Ⓣ which appeared as No 48 in the series in 1931.
• Mihailo Petrovic on Integration of Differential Equations .

558. Witold Hurewicz (1904-1956)
• He gave a series of lectures at Brown University in 1943 and these were published in mimeographed form by Brown University as Ordinary differential equations in the real domain with emphasis on geometric method.
• Lectures on ordinary differential equations was a reprinting, with minor revisions, of the mimeographed notes of his Brown University lectures.
• This textbook is a beautiful introduction to ordinary differential equations which again reflects the clarity of his thinking and the quality of his writing.

559. John Bell (1928-1990)
• We may say that when the state-vector is α+ or α- respectively, sz is equal to ℏ/2 and -ℏ/2 respectively, but, if one restricts oneself to the Schrodinger equation, sx and sy just do not have values.
• It is clear that we could try to recover realism and determinism if we allowed the view that the Schrodinger equation, and the wave-function or state-vector, might not contain all the information that is available about the system.
• Nevertheless it would appear natural that the possibility of supplementing the Schrodinger equation with hidden variables would have been taken seriously.

560. Christian Goldbach (1690-1764)
• He also studied equations and worked out in his correspondence with Euler how to provide a quick test for whether an algebraic equation has a rational root.

561. James McConnell (1915-1999)
• Very much the same as in the case of Einstein's field-equations of gravitation in empty space, Maxwell's equations likewise admit of a term expressing that the potentials act also as sources of the field-the "cosmical term," as it is usually called.
• A second use for the book is to provide probabilists with hard but clearly interesting problems in stochastic differential equations and which call for a more rigorous treatment.

562. Johann Rahn (1622-1676)
• The book, written in German, contains an example of Pell's equation.
• Pell's equation .
• History Topics: Pell's equation .

563. Edward Titchmarsh (1899-1963)
• Other topics to which he made major contributions included entire functions of a complex variable and, working with Hardy, integral equations.
• From 1939 Titchmarsh concentrated on the theory of series expansions of eigenfunctions of differential equations, work which helped to resolve problems in quantum mechanics.
• His work on this topic occupied him for the last 25 years of his life and he published much of it in Eigenfunction Expansions Associated with Second-Order Differential Equations (1946, 1958).

564. Maxim Kontsevich (1964-)
• A striking consequence is that it satisfies an infinite integrable hierarchy of Korteweg-de Vries equations completed by a so-called "string equation".

565. Abraham bar Hiyya (1070-1136)
• Rather strangely, however, 1145 was also the year that al-Khwarizmi's algebra book was translated by Robert of Chester so Abraham bar Hiyya's work was rapidly joined by a second text giving the complete solution to the general quadratic equation.
• History Topics: Quadratic, cubic and quartic equations .

566. Carl Borchardt (1817-1880)
• Borchardt's doctoral work, on non-linear differential equations, was supervised by Jacobi and submitted in 1843.
• Borchardt also generalised results of Kummer on equations determining the secular disturbances of the planets.
• In several further papers Borchardt applied the theory of determinants to algebraic equations, mostly in connection with symmetric functions, the theory of elimination, and interpolation.

567. Cheryl Praeger (1948-)
• Bernhard Neumann suggested a problem to her which she solved and so published her first paper Note on a functional equation while still an undergraduate.
• Praeger had studied the functional equation x(n+1) - x(n) = x2(n), where x2(n) = x(x(n)) and x is an integer-valued function of the integer variable n, and found a three-parameter family of solutions.
• In fact Praeger wrote one joint paper with her husband, Note on primitive permutation groups and a Diophantine equation, which was published by the journal Discrete Mathematics in 1980.

568. Sergei Novikov (1938-)
• We should mention especially Sergei's uncle Mstislav Keldysh who made major contributions to complex function theory, differential equations and applications to aerodynamics.
• These include a systematic study of finite-gap solutions of two-dimensional integrable systems, formulation of the equivalence of the classification of algebraic-geometric solutions of the KP equation with the conformal classification of Riemann surfaces, and work (with Krichever) on "almost commuting" operators that appear in string theory and matrix models ("Krichever-Novikov algebras", now widely used in physics).

569. Ennio De Giorgi (1928-1996)
• In 1955 De Giorgi gave an important example which showed nonuniqueness for solutions of the Cauchy problem for partial differential equations of parabolic type whose coefficents satisfy certain regularity conditions.
• In the following year he proved what has become known as "De Giorgi's Theorem" concerning the Holder continuity of solutions of elliptic partial differential equations of second order.
• The authors of this paper are all students of De Giorgi and they describe his contributions to geometric measure theory, the solution of Hilbert's XIXth problem in any dimension, the solution of the n-dimensional Plateau problem, the solution of the n-dimensional Bernstein problem, some results on partial differential equations in Gevrey spaces, convergence problems for functionals and operators, free boundary problems, semicontinuity and relaxation problems, minimum problems with free discontinuity set, and motion by mean curvature.

570. Joseph Wedderburn (1882-1948)
• He began mathematical research while still an undergraduate and his first paper, On the isoclinal lines of a differential equation of the first order was published in the Proceedings of The Royal Society of Edinburgh in 1903.
• Two other papers which he published in the same year in publications of the Royal Society of Edinburgh were on the scalar functions of a vector and on an application of quaternions to differential equations.

571. Jean Bourgain (1954-2018)
• Bourgain's work touches on several central topics of mathematical analysis: the geometry of Banach spaces, convexity in high dimensions, harmonic analysis, ergodic theory, and finally, nonlinear partial differential equations from mathematical physics.
• The paper [',' J Bourgain, Hamiltonian methods in nonlinear evolution equations, in M Atiyah and D Iagolnitzer (eds.), Fields Medallists’ Lectures (Singapore, 1997), 542-554.
• ','2] contains a survey relating to Bourgain's work on nonlinear partial differential equations from mathematical physics, including later results than was covered in the articles describing his work up to the award of the Fields Medal.

572. Elwin Christoffel (1829-1900)
• Christoffel published papers on function theory including conformal mappings, geometry and tensor analysis, Riemann's o-function, the theory of invariants, orthogonal polynomials and continued fractions, differential equations and potential theory, light, and shock waves.
• How does one compare someone who worked solely in one area with another who contributed to many areas? Again how does one compare someone who worked on differential equations with a geometer? Despite the obvious difficulties, and minor differences of opinion, it is still surprising how much agreement there is on such a ranking.
• It is difficult to compare a differential geometer with a function theorist, or those working on ordinary and partial differential equations with numerical analysts.

573. Eugène Rouché (1832-1910)
• In Comptes Rendus he published papers such as Sur la discussion des equations du premier degre Ⓣ (1875), Sur les lignes asymptotiques d'une surface du quatrieme degre Ⓣ (1877), Sur un probleme relatif a la duree du jeu Ⓣ (1888), and Sur la formule de Stirling Ⓣ (1890).
• The two-page paper Sur la discussion des equations du premier degre Ⓣ in volume 81 of Comptes Rendus of the Academie des Sciences contains his result on solving systems of linear equations.
• This is the well-known criterion which says that a system of linear equations has a solution if and only if the rank of the matrix of the associated homogeneous system is equal to the rank of the augumented matrix of the system.

574. Grigore Moisil (1906-1973)
• While working there he wrote the paper On a class of systems of equations with partial derivatives from mathematical physics.
• Before reading this work Moisil had worked on differential equations, the theory of functions and mechanics.
• Among Moisil's other books we mention: Associated matrices of systems of partial differential equations.

575. Willem de Sitter (1872-1934)
• He found solutions to Einstein's field equations in the absence of matter.
• This is a particularly simple solution of the field equations of general relativity for an expanding universe.
• He is not a cold, dispassionate juggler of Greek letters, a balancer of equations, but rather an artist in whom wild flights of the imagination are restrained by the formalism of a symbolic language and the evidence of observation.

576. Emilio Cafaro (1952-2015)
• Cafaro began publishing in 1984 when, in collaboration with N Bellomo and G Rizzi, he published On the mathematical modelling of physical systems by ordinary differential stochastic equations.
• This very interesting paper considers some physical systems in mechanics and relativistic mechanics modelled by stochastic differential equations (equations with random coefficients as well as initial conditions).

• Euclid's geometric solution of a quadratic equation .
• History Topics: Quadratic, cubic and quartic equations .

578. Henri Poincaré (1854-1912)
• His thesis was on differential equations and the examiners were somewhat critical of the work.
• The idea was to come in an indirect way from the work of his doctoral thesis on differential equations.
• He can be said to have been the originator of algebraic topology and, in 1901, he claimed that his researches in many different areas such as differential equations and multiple integrals had all led him to topology.

• The Dionysodorus we are interested in here is the mathematician Dionysodorus who Eutocius states solved the problem of the cubic equation using the intersection of a parabola and a hyperbola.
• Strabo distinguishes this Dionysodorus from Dionysodorus of Amisene and it is now thought that the Dionysodorus referred to by Pliny is not the mathematician who solved the problem of the cubic equation.
• Shortly after Cronert published details of the fragments of papyri relating to Dionysodorus which had been found at Herculaneum, Schmidt published a commentary on the material in which he argued convincingly that the Dionysodorus who solved the cubic equation using the intersection of a parabola and a hyperbola was the Dionysodorus of Caunus referred to in the Herculaneum papyrus.

580. Oskar Bolza (1857-1942)
• While at Clark, Bolza published the important paper On the theory of substitution groups and its application to algebraic equations in the American Journal of Mathematics.
• Immediately after his return to Germany Bolza continued teaching and research, in particular on function theory, integral equations and the calculus of variations.
• Bolza returned to Chicago for part of 1913 giving lecturers during the summer on function theory and integral equations.

581. Pafnuty Chebyshev (1821-1894)
• Chebyshev submitted a paper on The calculation of roots of equations in which he solved the equation y = f (x) by using a series expansion for the inverse function of f.

582. Morris Kline (1908-1992)
• His research publications during his first years as director of the Division of Electromagnetic Research, now in applied areas, included: Some Bessel equations and their application to guide and cavity theory (1948); A Bessel function expansion (1950); An asymptotic solution of Maxwell's equations (1950); and An asymptotic solution of linear second-order hyperbolic differential equations (1952).

583. Ivan Ivanovich Privalov (1891-1941)
• Of the mathematicians, Konstantin Alekseevich Andreev was best known for his work on geometry and was Dean of the Faculty during Privalov's undergraduate years, Dimitri Fedorovich Egorov was a leading researcher in differential geometry and integral equations, Leonid Kuzmich Lakhtin was interested in analysis and probability, and Boleslav Kornelievich Mlodzeevskii had been the first to give lectures at Moscow University on set theory and the theory of functions.
• He graduated from the University of Moscow in 1913 after being examined on his paper The reducibility problem in the theory of linear differential equations.
• Later textbook were: Fourier series (1930); Course of differential calculus (1934); Course of integral calculus (1934); Integral equations (1935); Foundation of the analysis of infinitesimals, textbook for self-education (1935); and Elements of the theory of elliptic functions (1939).

584. Georg Klügel (1739-1812)
• The reason for this is that analysis expresses the connection of the quantities by equations, and that it uses the general properties of the equations, as well as the rules for connecting them, to give the value of each quantity by those belonging together with it, or to develop their relations.
• While the synthetic method avails itself of such propositions which state an equality, it does not use algebraic equations.

585. John Scott Russell (1808-1882)
• This is now recognised as a fundamental ingredient in the theory of 'solitons', applicable to a wide class of nonlinear partial differential equations.
• In M Lakshmanan, Solitons, Springer Series in Nonlinear Dynamics, (New York, 1988) 150-281.','4] and [',' R K Bullough and P J Caudrey, Solitons and the Korteweg-de Vries Equation: Integrable Systems in 1834-1995.

586. William Oughtred (1574-1660)
• He even treats negative numbers as "numbers," although he does not allow these to be the solutions of equations.
• The work contains a considerable section on algebra, although this is still thought of geometrically as is shown by his rejection of negative numbers as solutions to equations.
• That they may not only learn their propositions, which is the highest point of Art that most Students aim at; but also may perceive with what solertiousness, by what engines of equations, interpretations, comparations, reductions, and disquisitions, those ancient Worthies have beautified, enlarged, and first found out this most excellent Science.

• The Sulbasutra of Baudhayana contains geometric solutions (but not algebraic ones) of a linear equation in a single unknown.
• Quadratic equations of the forms ax2 = c and ax2 + bx = c appear.

588. Karen Smith (1965-)
• A parabola, defined by the polynomial equation y = x2, is a familiar example of an algebraic variety.
• In general, algebraic varieties are defined by many equations in many unknowns, and can be quite complicated.

589. Charles Pisot (1910-1984)
• He then saw that he could get better and better approximations from the equation x2 - 2y2 = 1.
• There he looks at diophantine equations, the Goldbach conjecture, Roth's theorem, transcendental numbers, the distribution of primes, and p-adic analysis.

590. Aldo Andreotti (1924-1980)
• Perhaps his most famous results are his proof of the theorem of Leonida Tonelli (1958), his proof of the duality of Picard and Albanese varieties of algebraic surfaces, his work with A L Mayer on the Schottky problem (1967), and the Andreotti-Vesentini separation theorem which appeared in their joint 1965 paper Carleman estimates for the Laplace-Beltrami equation on complex manifolds.
• The author extends various classical results of the theory of Cauchy-Riemann equations to general complexes of linear partial differential operators.

591. Alexis Fontaine (1704-1771)
• His papers are rather confused, and ignorant of the work of others, but do contain some very original ideas in the calculus of variations, differential equations and the theory of equations.
• 11 (1) (1984), 22-38.','3] and also in [',' J L Greenberg, Alexis Fontaine’s integration of ordinary differential equations and the origins of the calculus of several variables, Ann.

592. Étienne Bobillier (1798-1840)
• The second and the third Books, deal with the solution of problems, and the equations which derive from them; the latter, with certain algebraic methods which enable numerical calculations to be shortened.
• He first set up a problem in the form of an equation in a particular case, simple enough so that the analytic geometry of his time could deal with it.

593. Wilhelm Killing (1847-1923)
• Lie algebras were introduced by Lie in about 1870 in his work on differential equations.
• Finally, before we leave our discussion of Killing's work, it is worth noting that he introduced the term 'characteristic equation' of a matrix.

594. Carl Friedrich Gauss (1777-1855)
• In the first volume he discussed differential equations, conic sections and elliptic orbits, while in the second volume, the main part of the work, he showed how to estimate and then to refine the estimation of a planet's orbit.
• Gauss used the Laplace equation to aid him with his calculations, and ended up specifying a location for the magnetic South pole.

595. Gaston Darboux (1842-1917)
• Darboux generalised results of Kummer giving a system defined by a single equation with many interesting properties.
• This integral was introduced in a paper on differential equations of the second order which he wrote in 1870.

596. Ernst Straus (1922-1983)
• An approximate solution of the field equations for empty space is obtained and the gravitational potentials thus determined are required to piece together continuously with the known gravitational potentials for a pressure free, spatially constant density of matter.
• This presented a new derivation of the field equations which was necessary since the derivation in Einstein's single authored paper published in the previous year was based on an error.
• Algebraic equations satisfied by roots of natural numbers.

597. Nikolai Ivanovich Lobachevsky (1792-1856)
• Despite this heavy administrative load, Lobachevsky continued to teach a variety of different topics such as mechanics, hydrodynamics, integration, differential equations, the calculus of variations, and mathematical physics.
• In 1834 Lobachevsky found a method for the approximation of the roots of algebraic equations.
• This method of numerical solution of algebraic equations, developed independently by Graffe to answer a prize question of the Berlin Academy, is today a particularly suitable method for using computers to solve such problems.

598. Theodoros Varopoulos (1894-1957)
• Impetuous and imaginative in research, Remoundos, with his fascinating lectures and distinguished presence, produced a stream of research in multivariable complex equations, which influenced the great centre of mathematical analysis in Paris.
• This was one of four papers Varopoulos published in the Comptes Rendus of the French Academy of Sciences in 1920, the others being Sur les fonctions algebroides et les fonctions croissantes Ⓣ, Sur une classe de fonctions a un nombre infini de branches Ⓣ, and Sur les zeros et les integrales d'une class d'equations differentielles Ⓣ.
• The identification of real roots of ordinary differential equations with real coefficients began in Greece with Panagiotis Zervos.
• The corresponding work for the complex roots of equations with complex coefficients appears in work by G Remoundos and was continued by his student Spyridon Sarantopoulos, but wis mainly developed by Varopoulos and Paul Montel.

599. Eugenio Levi (1883-1917)
• This important work studied partial differential equations of order 2n, linear in two variables fully elliptic in a certain region of the plane.
• Since the problem could not be solved in general, he examined special cases starting with linear equations in two variables and then extending the ideas to the non-linear case.
• However, he also wrote on issues relating to: differential geometry, Lie groups, partial differential equations and the minimum principle.

600. Frank Cole (1861-1926)
• Cole returned to Harvard and wrote a thesis A Contribution to the Theory of the General Equation of the Sixth Degree which, as the title indicates, studied equations of degree 6.

601. Gustav Herglotz (1881-1953)
• In this last paper Herglotz solved Abel's integral equation which results from the inversion of measured seismic travel times into a velocity-depth function.
• There are two sections, one of five chapters on classical theory of the mechanics of continua based on Hamilton's principle and another of four chapters on partial differential equations.

602. Stanisaw Zaremba (1863-1942)
• Much of Zaremba's research work was in partial differential equations and potential theory.
• He studied elliptic equations and in particular contributed to the Dirichlet principle.
• And as for my speciality, why, how could I forget the splendid results in the domain of mixed boundary problems and of harmonic functions, as well as of hyperbolic equations, research by means of which he opened a new path along which contemporary knowledge will proceed in the near future.

603. Jean-Claude Bouquet (1819-1885)
• Bouquet and Briot developed Cauchy's work on the existence of integrals of a differential equation.
• For example Etude des fonctions d'une variable imaginaire Ⓣ; < (Research on the properties of functions defined by differential equations); and Memoire sur l'integration des equations differentielles au moyen des fonctions elliptiques.

604. Paul Painlevé (1863-1933)
• He worked on differential equations, particularly studying their singular points, and on mechanics.
• His interest in mechanics was a natural one since this subject provided a natural setting for applications of the results which he had proved for differential equations.
• He solved, using Painleve functions, differential equations which Poincare and Emile Picard had failed to solve, showing, as Hadamard wrote, that:- .

605. Ulugh Beg (1393-1449)
• This excellent book records the main achievements which include the following: methods for giving accurate approximate solutions of cubic equations; work with the binomial theorem; Ulugh Beg's accurate tables of sines and tangents correct to eight decimal places; formulae of spherical trigonometry; and of particular importance, Ulugh Beg's Catalogue of the stars, the first comprehensive stellar catalogue since that of Ptolemy.
• The calculation is built on an accurate determination of sin 1° which Ulugh Beg solved by showing it to be the solution of a cubic equation which he then solved by numerical methods.

606. Gustav Kirchhoff (1824-1887)
• Kirchhoff considered an electrical network consisting of circuits joined at nodes of the network and gave laws which reduce the calculation of the currents in each loop to the solution of algebraic equations.
• An early form of the theory had been developed by Germain and Poisson but it was Navier who gave the correct differential equation a few years later.

607. Mei Wending (1633-1721)
• Mei's first mathematical work was the Fangcheng lun (On simultaneous linear equations) which he wrote in 1672.
• Indeed, Western missionaries who went to China in the 16th and 17th centuries did not mention simultaneous linear equations because the subject was then only in its infancy in the West.
• Mei Wending clearly wished to demonstrate the superiority of early Chinese mathematics over the methods Western scholars had brought to China, and at least in this case, the example of simultaneous linear equations was an excellent one to stress.

608. Paul Cohen (1934-2007)
• In addition to his work on set theory, Cohen worked on differential equation and harmonic analysis.
• Like many great mathematicians, his mathematical interests and contributions were very broad, ranging from mathematical analysis and differential equations to mathematical logic and number theory.

609. Sophie Germain (1776-1831)
• Lagrange, who was one of the judges in the contest, corrected the errors in Germain's calculations and came up with an equation that he believed might describe Chladni's patterns.
• She demonstrated that Lagrange's equation did yield Chladni's patterns in several cases, but could not give a satisfactory derivation of Lagrange's equation from physical principles.

610. Daniel Pedoe (1910-1998)
• While a pupil at the Central Foundation Boys' School, Pedoe published his first paper The geometric interpretation of Cagnoli's equation: sin b sin c + cos b cos c cos A = sin B sin C - cos B cos C cos a which appeared in 1929 in the Mathematical Gazette.
• II; Salmon, Conic Sections; Hobson, Trigonometry; Burnside and Panton, Theory of Equations; Routh, Dynamics of a Particle and Rigid Bodies; Minchin, Statics, including Theory of Attractions.

611. Evgenii Mikhailovich Lifshitz (1915-1985)
• The requirements were: ability to evaluate any indefinite integral (in terms of elementary functions) and to solve any ordinary differential equation of the standard type, knowledge of vector analysis and tensor algebra as well as of principles of the theory of functions of complex variable (theory of residues, Laplace method).
• This 1974 prize was awarded jointly to Lifshitz, V A Belinskii and I M Khalatnikov for their work on the singularities of cosmological solutions of the gravitational equations which was presented in sixteen papers between 1961 and 1985.

612. A A Krishnaswami Ayyangar (1892-1953)
• His papers include: Ancient Hindu Mathematics (1921); The Hindu sine Table (1923-24); The mathematics of Aryabhata (1926); The Hindu Arabic numerals (2 parts) (1928,1929); Bhaskara and samclishta kuttaka (1929-30); New light on Bhaskara's chakravala or cyclic method of solving indeterminate equations of the second degree in two variables (1929-30); New proofs of old theorems - Apollonius and Brahmagupta (1920-30); Astronomy - past and present (1930); Some glimpses of ancient Hindu mathematics (1933); Fourteen calendars (1937); A new continued fraction (1937-38); The Bhakshali manuscript (1939); Theory of the nearest square continued fraction (2 parts) (1940, 1941); Peeps into India's mathematical past (1945); and Remarks on Bhaskara's approximation to the sine of an angle (1950).
• He read the paper On the Sexi-Sectional Equation at a meeting of the Society on Friday 7 November 1924.

613. Kunihiko Kodaira (1915-1997)
• These include applications of Hilbert space methods to differential equations which was an important topic in his early work and was largely the result of influence by Weyl.
• In 1979 he published the five volume Introduction to analysis in Japanese covering real numbers, functions, differentiation, integration, infinite series, functions of several variables, curves and surfaces, Fourier series, Fourier transforms, ordinary differential equations, and distributions.
• In mathematics and science it is a familiar occurrence to have objects, such as systems of equations, depending on parameters.

614. Boris Yakovlevich Levin (1906-1993)
• Morduhai-Boltovskoi had Levin undertaking research from his second year of study, proposing a problem to him about generalising the functional equation for the Euler G-function.
• He was already publishing papers and, in addition to the one we mentioned above, he had published The arithmetic properties of holomorphic functions (1933), The intersection of algebraic curves (1934), Entire functions of irregular growth (1936), and The growth of the Sturm-Liouville integral equation (1936).
• Of his results on the spectral theory of differential operators we shall mention only the construction, dating from the 50's, of the operator "attached to infinity" of the transformation for the Schrodinger equation, which played an important part in the solution of the inverse problem in the theory of scattering.

615. Georg Zehfuss (1832-1901)
• During these years he taught arithmetic, algebra and geometry, differential calculus, theory of definite integrals, elliptic functions, theory of higher equations, analytical geometry of the plane and of 3-space, and analytical mechanics.
• At this school he taught algebraic analysis, trigonometry, the theory of higher degree equations, two dimensional analytic geometry, mechanics, differential and integral calculus, and three dimensional analytic geometry.
• Although Zehfuss is best known for his contributions to determinants, he made other contributions to mathematics in difference equations, differential and integral calculus and combinatorics.

616. Anders Wiman (1865-1959)
• One of the topics that Wiman studied was the solubility of algebraic equations.
• For example, in Uber die metacyklischen Gleichungen von Primzahlgrad Ⓣ published in the volume of Acta Mathematica dedicated to the memory of Niels Abel, he studied the Galois group of soluble equations of prime degree.
• For example, Wiman-Valiron theory, Wiman-Valiron discs, Wiman theorems for quasiregular mappings, Wiman surfaces, the Wiman inequality, Wiman's sextic, the Wiman-Valiron method for difference equations, the conjecture of Wiman, and the Wiman bound.

617. Gabriel Lamé (1795-1870)
• He used them to transform Laplace's equation into ellipsoidal coordinates and so separate the variables and solve the resulting equation.
• This happened with curvilinear coordinates for he was led to study the equation .

618. Ernest William Barnes (1874-1953)
• His early work was concerned with various aspects of the gamma function, including generalisations of this function given by the so-called Barnes G-function, which satisfies the equation .
• He also considered second-order linear difference equations connected with the .

619. Andre-Louis Cholesky (1875-1918)
• To solve the condition equations in the method of least squares, Cholesky invented a very ingenious computational procedure which immediately proved extremely useful: it is now known as the Method of Cholesky and we describe it below.
• After his death one of his fellow officers, Commandant Benoit, published Cholesky's method of computing solutions to the normal equations for some least squares data fitting problems in Note sur une methode de resolution des equations normales provenant de l'application de la methode des moindres carres a un systeme d'equations lineaires en nombre inferieure a celui des inconnues.
• Application de la methode a la resolution d'un systeme defini d'equations lineaires (Procede du Commandant Cholesky) Ⓣ, published in the Bulletin geodesique in 1924.
• The beauty of the method is that it is trivial to solve equations of the type Mx = b when M is a triangular matrix.

620. Stefan Kaczmarz (1895-1939)
• On 13 October 1924, Kaczmarz was awarded his doctorate for his thesis The relationships between certain functional and differential equations.
• He published results from his thesis in his first paper Sur l'equation fonctionnelle f (x) + f (x + y) = φ(y) f (x + y/2) Ⓣ which appeared in Fundamenta Mathematicae in 1924.
• From 1923 to 1939 Kaczmarz taught many university level courses at Lwow such as: Analytical Geometry, Higher Analysis, Integral Equations, Algebraic Curves, Trigonometric Series, Non-Euclidean Geometry and the Theory of Groups, and Differential Geometry.
• There is Kaczmarz's algorithm for the approximate solution for systems of linear equations which appears in his paper Angenaherte Auflosung von Systemen linearer Gleichungen Ⓣ published in the Bulletin International de l'Academie Polonaise des Sciences et des Lettres in 1937.

621. Alfred Tauber (1866-1942)
• Of lesser importance is Tauber's work on differential equations and the gamma function, but let us give the title of one of his papers on this latter topic, namely uber die unvollstandigen Gammafunktionen (1906).
• In particular his papers Uber die Hypothekenversicherung Ⓣ (1897) and Gutachten fur die sechste internationale Tagung der Versicherungswissenschaften Ⓣ (1909) contain his formulation of the Tisiko equation.

622. Alfred Tarski (1901-1983)
• In 1968 Tarski wrote another famous paper Equational logic and equational theories of algebras in which he presented a survey of the metamathematics of equational logic as it then existed as well as giving some new results and some open problems.

623. Gaston Julia (1893-1978)
• Volume 3 contains four parts: (i) Functional equations and conformal mapping; (ii) Conformal mapping; (iii) General lectures; and (iv) Isolated works in analysis on Implicit function defined by the vanishing of an active function, and on certain series.
• Volume 4 is again in four parts: (i) Functional calculus and integral equations; (ii) Quasianalyticity; (iii) Various techniques of analysis; and (iv) Works concerning Hilbert space.
• The applications to the theory of matrices and equations, which are largely implicit, in certain of the more abstract treatments, are elaborated here with a wealth of detail which renders them unusually accessible to the student.

624. Karl Sundman (1873-1949)
• To regularize the singularity of the differential equations of motion, in the 1912 paper mentioned above, Sundman introduced a new independent variable which regularizes the motion within a band of finite breadth.
• It is a matter of construction a machine for solving systems of second order differential equations.
• Although designed to calculate astronomical perturbations, the machine essentially functions as an integrator for differential equations and could be used for a large number of other problems.

625. Karl Mollweide (1774-1825)
• The second piece of work to which Mollweide's name is attached today is the Mollweide equations which are sometimes called Mollweide's formulas.
• One of the more puzzling aspects is why these equations should have become known as the Mollweide equations since in the 1808 paper in which they appear Mollweide refers the book by Antonio Cagnoli (1743-1816) Traite de Trigonometrie Rectiligne et Spherique, Contenant des Methodes et des Formules Nouvelles, avec des Applications a la Plupart des Problemes de l'astronomie Ⓣ (1786) which contains the formulas.

626. Derrick Henry Lehmer (1905-1991)
• The chapter headings are: Lucas's functions; Tests for primality; Continued fractions; Bernoulli numbers and polynomials; Diophantine equations; Numerical functions; Matrices; Power residues; Analytic number theory; Partitions; Modular forms; Cyclotomy; Combinatorics; Sieves; Equation solving; Computing techniques; and Miscellaneous.

627. Srinivasa Ramanujan (1887-1920)
• Ramanujan was shown how to solve cubic equations in 1902 and he went on to find his own method to solve the quartic.
• He devoloped relations between elliptic modular equations in 1910.
• Ramanujan worked out the Riemann series, the elliptic integrals, hypergeometric series and functional equations of the zeta function.

628. Isaac Schoenberg (1903-1990)
• syllabus: 'Differential Geometry', taught by Alexandru Myller; and 'Differential Equations including Fuchs Theory', taught by Simion Sanielevici.
• These papers are: (with Gilbert Bliss) On separation, comparison, and oscillation theorems for self-adjoint systems of linear second order differential equations (1931); The minimizing properties of geodesic arcs with conjugate end points (1931); On finite and infinite completely monotonic sequences (1932); On finite-rowed systems of linear inequalities in infinitely many variables I (1932); On finite-rowed systems of linear inequalities in infinitely many variables II (1932); (with Gilbert Bliss) On the derivation of necessary conditions for the problem of Bolza (1932); and Some applications of the calculus of variations to Riemannian geometry (1932).
• Schoenberg is noted worldwide for his realisation of the importance of spline functions for general mathematical analysis and in approximation theory, their key relevance in numerical procedures for solving differential equations with initial and/or boundary conditions, and their role in the solution of a whole host of variational problems.

629. Panagiotis Zervos (1878-1952)
• At this time, in addition to his teaching duties, Zervos was undertaking research attempting to determine the exact number of positive roots of algebraic equations with real factors.
• The Monge problem in one independent variable, in the broad sense, consists of explicitly integrating a system of k (k ≤ n - 1) Monge equations: .
• He attended the International Congress of Mathematicians held in Rome in April 1908 and gave the talk Sur la correspondance entre les theories d'integration des equations aux drivees partielles du premier ordre et d'integration des systemes de Monge Ⓣ in Section I: Arithmetic, Algebra, and Analysis.
• Zervos's results were presented to the International Congress of Mathematicians in Cambridge, England, in August 1912 as the lecture Sur les equations aux derivees partielles du premier ordre a trois variables independantes Ⓣ.
• Zervos was able to generalise Hilbert's results and published these in Sur l'integration de certains systemes indetermines d'equations Ⓣ which appeared in Crelle's Journal.
• The Society began publication of the Bulletin of the Greek Mathematical Society in 1919 and Zervos published two papers in French in the first volume, namely Sur l'equivalence des systemes d'equations differentielles Ⓣ and Sur quelques remarques relatives aux theories de l'integration des systemes en involution du second ordre Ⓣ.
• The conference proceedings were published and it contained two papers by Zervos, both written in French, namely Sur quelques equations differentielles indeterminees Ⓣ and Sur l'integration des systemes differentiels indetermines Ⓣ.

630. Alston Householder (1904-1993)
• He started publishing on this new topic with Some numerical methods for solving systems of linear equations which appeared in 1950.
• In a remarkable series of papers he effectively classified the algorithms for solving linear equations and computing eigensystems, showing that in many cases essentially the same algorithm had been presented in a large variety of superficially quite different algorithms.

631. Eduard Stiefel (1909-1978)
• They feel that from the point of view of the applications to stability and vibrational questions in mechanics the variational approach is the most suitable one (as compared with the approach by differential or integral equations).
• Whenever possible, we derive the basic differential equations or at least we interpret them.

632. Aleksandr Nekrasov (1883-1957)
• He also investigated mathematical questions which were related to these applications, in particular writing important works on non-linear integral equations.
• In the same year another important work on the applications of integral equations to aerodynamics was published.

633. Albert Einstein (1879-1955)
• This seemed to contradict classical electromagnetic theory, based on Maxwell's equations and the laws of thermodynamics which assumed that electromagnetic energy consisted of waves which could contain any small amount of energy.
• In fact Hilbert submitted for publication, a week before Einstein completed his work, a paper which contains the correct field equations of general relativity.

• He worked on how to derive class number relations from modular equations.
• Further topics studied by Hurwitz include complex function theory, the roots of Bessel functions, and difference equations.

635. Franz Aepinus (1724-1802)
• During this period he undertook research in several different areas of mathematics including algebraic equations, solving partial differential equations, and on negative numbers.

636. Taro Morishima (1903-1989)
• This paper On the Diophantine equation xp + yp = czp published in the Proceedings of the American Mathematical Society was, as all of Morishima's work, subject to the criticism that he did not give full enough explanations.
• The authors obtain elegant criteria generalising the classical Wieferich and Mirimanoff criteria for the first case of Fermat's equation.

637. Aurel Wintner (1903-1958)
• Wintner published on analysis, number theory, differential equations and probability (with several joint papers with Norbert Wiener).
• A study of certain astronomical equations led Wintner to consider almost periodic functions.

638. Clement Durell (1882-1968)
• Contents include the properties of the triangle and the quadrilateral; equations, sub-multiple angles, and inverse functions; hyperbolic, logarithmic, and exponential functions; and expansions in power-series.
• Further topics encompass the special hyperbolic functions; projection and finite series; complex numbers; de Moivre's theorem and its applications; one- and many-valued functions of a complex variable; and roots of equations.

639. Thomas Hakon Grönwall (1877-1932)
• In 1898, at the age 21, he was the author of ten mathematical papers and received his doctor's degree at Uppsala University for the thesis On system of linear total differential equations particularly with 2n-periodic coefficients.
• Gronwall's work contains classical analysis (Fourier series, Gibbs phenomenon, summability theory, Laplace and Legendre series), differential and integral equations, analytic number theory (transcendental numbers, divisor function, L-function of Dirichlet), complex function theory (Dirichlet L-series, conformal mappings, univalent functions), differential geometry, mathematical physics (problems of elasticity, ballistics, induction, potential theory, kinetic theory of gases, optics), nomography, atomic physics (wave mechanics of hydrogen and helium atom, lattice theory of crystals) and physical chemistry where he is especially known as a very important contributor.

640. Arthur Milne (1896-1950)
• Milne combined the two approaches and came up with an integral equation of great mathematical interest which is now known as Milne's integral equation.

641. Eugene Lukacs (1906-1987)
• In 1942 Lukacs had made an important contribution to mathematical statistics by introducing, for the first time, the method of differential equations in characteristic function theory.
• Other topics to which Lukacs made major contributions include characterisations of distributions, stability of characterisation results and functional equations.

642. Pierre Laurent (1813-1854)
• Find the limiting equations that must be joined to the indefinite equations in order to determine completely the maxima and minima of multiple integrals.

643. Victor Bäcklund (1845-1922)
• All the candidates gave lectures and, because he was not already on the staff of a university, Bjorling was asked to defend one of his recently published papers on roots of algebraic equations.
• It was in this new area of differential equations that Backlund produced his more notable results, namely on what are today called Backlund transformations.

644. Jim Wilkinson (1919-1986)
• He began to put his greatest efforts into the numerical solution of hyperbolic partial differential equations, using finite difference methods and the method of characteristics.
• He worked on numerical methods for solving systems of linear equations and eigenvalue problems.

645. David Crighton (1942-2000)
• He gave a mathematical model in which the problem reduce to solving two singular integral equations with Cauchy-type kernels, and with variable coefficients.
• Solving the equations he showed that he boundary converts the energy stored in the turbulent boundary layer into the sound waves which generate noise.

646. Paul Butzer (1928-)
• Moreover, it has already become indispensable in classical approximation theory, in the study of the initial and boundary behaviour of solutions of partial differential equations and in the theory of singular integrals, because of the new results obtained by the authors in these areas.
• Special as this approach may seem, it not only embraces many of the topics of the classical theory but also leads to significant new results, e.g., on summation processes of Fourier series, conjugate functions, fractional integration and differentiation, limiting behaviour of solutions of partial differential equations, and saturation theory.

647. Israil Gelfand (1913-2009)
• Another important area of his work is that on differential equations where he worked on the inverse Sturm-Liouville problem.
• He worked on computational mathematics, developing general methods for solving the equations of mathematical physics by numerical means.

648. Attia Ashour (1924-2017)
• The disk is regarded as composed of a large number of concentric annular circuits, and the problem thereby reduced to the solution of a Fredholm integral equation.
• Two methods of solving this equation are described and illustrated with a numerical example.

649. Sofia Kovalevskaya (1850-1891)
• The three papers were on Partial differential equations, Abelian integrals and Saturn's Rings.
• The first of these three articles was still a valuable paper however, because it contained an exposition of Weierstrass's theory for integrating certain partial differential equations.

650. Matteo Bottasso (1878-1918)
• Torino, 1912) Bottasso underlined the analogy between vector homography and integral equations, and used vector homography to solve integral equations.

651. Nkechi Agwu (1962-)
• She had undertaken an honours project "On the stability of solutions of constant coefficient second order equations and systems," advised by James Ezeilo.
• She chaired a Mathematical Association of America team which developed historical modules in "Linear equations and polynomials".

652. Laila Soueif (1956-)
• I was always happiest when I was solving equations.
• There is the abstraction, the understanding of where things come from, and there is also the technical side, of creating mechanisms to solve equations.

653. Giacinto Morera (1856-1907)
• Morera studied the fundamental problems which arise in dynamics with particular regard to the use of the Pfaff method applied to Jacobian systems of partial differential equations and to the problem of Lie transformations of the canonical equations of motion.

654. Andrzej Alexiewicz (1917-1995)
• In fact, because of the disruption caused by the war, his habilitation thesis was published before his doctoral thesis, but he had already a number of earlier publications such as: (with W Orlicz) Remarque sur l'equation fonctionelle f (x + y) = f (x) + f (y) Ⓣ (1945); Linear operations among bounded measurable functions I and II (1946); On Hausdorff classes (1947); On multiplication of infinite series (1948); and Linear functionals on Denjoy-integrable functions (1948).
• Scalar and vector measurable functions; sequences of linear operators; the Denjoy integral; differentiation of vector functions; differential equations and equations with vector functions; two norm spaces and two norm algebras and their applications in summability theory; analytic functions; and applications of functional analysis to classical problems of mathematical analysis.

655. Lajos Martin (1827-1897)
• Making physically and technically untenable simplifications, he put down the equation he had figured out, and although the contraptions constructed on its basis all failed at the testing, martin deemed it justified to publish his theoretical findings.
• In a reply in a highly ironical tome [Application of the differential coefficient for solving the equation of the propeller surface (Hungarian) (1877)] he called Szily's variational method an unnecessary and erroneous extravagance.

656. Israel Gohberg (1928-2009)
• In addition to Gohberg's outstanding work in analysis and in particular in operator theory and matrix methods, he founded the major international journal Integral equations and operator theory in the late 1980s.
• is devoted to the publication of current research in integral equations, operator theory and related topics with emphasis on the linear aspects of the theory.

657. Thorvald Thiele (1838-1910)
• One of his most important contributions to actuarial science was a differential equation for the net premium reserve Vt at time t for a life insurance, namely .
• Although, as we have said, this differential equation is Thiele's most significant contribution to actuarial science, he never published the result.

658. Enrico Bombieri (1940-)
• The award was made for his major contributions to the study of the prime numbers, to the study of univalent functions and the local Bieberbach conjecture, to the theory of functions of several complex variables, and to the theory of partial differential equations and minimal surfaces.
• He has significantly influenced number theory, algebraic geometry, partial differential equations, several complex variables, and the theory of finite groups.

659. Arthur Hirsch (1866-1948)
• He taught 'differential equations, variational calculus and hypergeometric integrals of higher order' [','http://www.library.ethz.ch/de/Ressourcen/Digitale-Kollektionen/Kurzportraets/Arthur-Hirsch-1866-1948','5], mainly to future engineers, 'but he did not leave too many marks' [','http://www.library.ethz.ch/de/Ressourcen/Digitale-Kollektionen/Kurzportraets/Arthur-Hirsch-1866-1948','5].
• Hirsch published a few papers in Mathematische Annalen, primarily on differential equations and integrals.

• In mathematics he took lecture courses by Hans Hahn (one on Theoretical arithmetic and one on the Foundations of geometry), Wilhelm Wirtinger (Ordinary differential equations) and Franz Mertens (one on Algebra and one on Number theory) among others.
• While creating a theory of absolutely additive set functions which, heretofore, has barely been investigated, the author succeeds with the development of a theory that contains the theory of integral equations, linear and bilinear forms in infinitely many variables, as a special case.

661. Wilhelm Cauer (1900-1945)
• Interested in using computers to solve systems of linear equations, he contacted Richard Courant at Gottingen and Vannevar Bush who was developing mechanical computers at the Massachusetts Institute of Technology.
• Back in Gottingen he wanted to build a calculating machine to solve linear equations but, despite having progressed well with the project, this was a time when funding was impossible due to the Depression so it could not proceed.

662. Leonida Tonelli (1885-1946)
• The fourth, and final, volume Argomenti vari Ⓣ, published in 1963, contains papers on trigonometric series, ordinary differential equations and integral equations (all published in or after 1924-25), and some miscellaneous work (from 1909 onwards), including Tonelli's biography of Salvatore Pincherle.

663. Kenneth May (1915-1977)
• Evans had many different mathematical interests including potential theory, functional analysis and integral equations.
• His report was entitled 'Galois Theory of Equations' and was a historical essay.

664. Michele Cipolla (1880-1947)
• The work includes the theory of abstract groups, the theory of groups of substitutions, and Galois's theory of algebraic equations.
• Also with Vincenzo Amato (1881-1963), another of his students in Catania who studied the properties of those algebraic equations whose Galois group was the fundamental subgroup of the whole group, he wrote secondary school texts such as Algebra elementare : per il ginnasio superiore e per le classi 3 e 4 dell'istituto magistrale inferiore Ⓣ (1926), and Aritmetica prattica per le scuole industriale.

665. Iacopo Barsotti (1921-1987)
• He moved to this in Theta functions in positive characteristic (1979) and, staying with the theme of theta functions, published Differential equations of theta functions (1983) and Theta functions and differential equations (1985).

666. Herbert Federer (1920-2010)
• He was building on work by Lamberto Cesari who had studied surfaces given by parametric equations, in particular the Lebesgue area of such a surface, while at Pisa from 1938 to 1942.
• It has depth and beauty of its own, but its greatest worth should be in its effect on other areas of mathematics, e.g., differential geometry, differential topology, partial differential equations, algebraic geometry, potential theory.

667. Philippe de la Hire (1640-1718)
• He began with their focal definitions and applied Cartesian analytic geometry t the study of equations and the solution of indeterminate problems; he also displayed the Cartesian method for solving certain types of equations by intersections of curves.

668. Osip Somov (1815-1876)
• During this time he wrote his first mathematical work on algebraic equations Theory of determinate algebraic equations of higher degree which was published in 1838 [',' A T Grigorian, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1].

669. Dmitry Aleksandrovich Grave (1863-1939)
• He obtained his masters degree in 1889 (equivalent to a Ph.D.) for his thesis On the Integration of Partial Differential Equations of the First Order (Russian) and, in the autumn of that year, began teaching at the University of St Petersburg.
• In particular he worked on Galois theory, ideals and equations of the fifth degree.

670. Georg Scheffers (1866-1945)
• A new chapter on implicit functions, with a thorough discussion of the functional determinant and of the independence of functions and of equations has been inserted.
• He is not therefore concerned with the equations of the projections, and though a certain amount of mathematics is necessary for his purpose, yet he concerns himself as far as possible with the geometrical constructions of the parallels and meridians, rather than with the trigonometrical calculations of their positions and sizes.

671. Hendrik Kloosterman (1900-1968)
• Kloosterman was examining the number of solutions in integers xn, to the equation .
• He had managed to find, provided s ≥ 5 and the an satisfy suitable congruence conditions, an asymptotic formula for the number of solution to the equation (*).

672. Pierre Boutroux (1880-1922)
• There he lectured at the College de France on functions which are the solutions of first order differential equations.
• He worked on multiform functions and also continued Painleve's work on singularities of differential equations.

673. Paul Mansion (1844-1919)
• The Royal Belgium Academy of Science proposed for its prize competition for 1871 the task "to summarise and simplify the theory of partial differential equations of the first two orders".
• This was a vast and difficult undertaking and Mansion decided to enter but to restrict himself to the theory of first order partial differential equations.
• Mansion submitted the 289-page memoir Memoire sur la theorie des equations aux derivees partielles du premier ordre which was judged the winning entry.

674. Simion Stoilow (1887-1961)
• Stoilow's thesis advisor was Emile Picard, and in 1914 he submitted his doctoral thesis Sur une classe de fonctions de deux variables definies par les equations lineaires aux derivees partielles Ⓣ.
• He did, however, publish his first paper in 1914, namely Sur les integrales des equations lineaires aux derivees partielles a deux variables independantes Ⓣ.
• He published two further papers, namely Sur les fonctions quadruplement periodiques Ⓣ (1915) and Sur l'integration des equations lineaires aux derivees partielles et la methode des approximations successives Ⓣ (1916), before publishing his doctoral thesis in 1916.
• He published three further papers in 1919 including Sur les singularites mobiles des integrales des equations lineaires aux derivees partielles et sur leur integrale generale Ⓣ, and two further papers in 1920.
• Before he took up his first university appointment in 1919, Stoilow concentrated on the theory of partial differential equations in the complex domain.

675. Vilhelm Bjerknes (1862-1951)
• Vilhelm Bjerknes and his associates at Bergen succeeded in devising equations relating the measurable components of weather, but their complexity precluded the rapid solutions needed for forecasting.
• The next step forward in the mathematical approach was due to Richardson in 1922 when he reduced the complicated equations produced by Bjerknes's Bergen School to long series of simple arithmetic operations.

676. Gottfried Leibniz (1646-1716)
• Another major mathematical work by Leibniz was his work on determinants which arose from his developing methods to solve systems of linear equations.
• History Topics: Quadratic, cubic and quartic equations .

677. Andrew Forsyth (1858-1942)
• Famous texts which Forsyth published before his 1893 work Theory of Functions of a complex variable , are A treatise on differential equations (1885), and Theory of differential equations published in six volumes between 1890 and 1906.

678. Hermann Brück (1905-2000)
• In mathematics he took us up to number theory, analytical and spherical geometry and the calculus, including differential equations.
• Though I found myself at the wrong end of his 6-semester course on theoretical physics, I was able to keep up quite well with his lectures even in my first semester - partial differential equations of physics - introduced with a discussion of Fourier's work.

679. Steven Orszag (1943-2011)
• The title of this volume is somewhat misleading in that the subjects discussed are approximate analytic solutions of ordinary differential and difference equations, and no other topics are considered.
• It is not only the authors who hope for a similar book on approximate solutions of partial differential equations.

680. Michel Plancherel (1885-1967)
• He applied his results in the theory of hyperbolic and parabolic partial differential equations.
• In algebra Plancherel obtained results on quadratic forms and their applications, to the solvability of systems of equations with infinitely many variables and to the theory of commutative Hilbert algebras (theorem of Plancherel-Godement).

681. Otto Toeplitz (1881-1940)
• When he arrived there Hilbert was completing his theory of integral equations.
• A major joint project with Hellinger to write a major encyclopaedia article on integral equations, which they worked on for many years, was completed during this time and appeared in print in 1927.

682. Luca Pacioli (1445-1517)
• During this time Pacioli worked with Scipione del Ferro and there has been much conjecture as to whether the two discussed the algebraic solution of cubic equations.
• History Topics: Quadratic, cubic and quartic equations .

683. Wilhelm Kutta (1867-1944)
• It contains the now famous Runge-Kutta method for solving ordinary differential equations.
• The former contains the Runge-Kutta method for solving ordinary differential equations while the latter contains the Zhukovsky-Kutta (or Joukowski-Kutta) theorem giving the lift on an aerofoil.

684. Paul Epstein (1871-1939)
• However Mr Christoffel only sought to study the behaviour of the integrals at infinity, and gave the important equation (7) in §2 without proof.
• He proved a functional equation, the analytic continuation and the Kronecker limit formula for these functions.

685. Thomas Scott Fiske (1865-1944)
• His main courses were in the theory of functions and differential equations.
• W(illiam) Benjamin Fite (1869-1932) was teaching 'Advanced calculus', and 'Differential equations'; Frank Nelson Cole was teaching 'Algebra'; George Adams Pfeiffer (1889-1943) was teaching 'Analysis situs'; Joseph Fels Ritt was teaching 'Topics in theory of functions'; Edward Kasner was running the 'Seminar in differential geometry'; David Eugene Smith was teaching 'History of mathematics', and 'Practicum in the history of mathematics'; while Cassius Jackson Keyser (1862-1947) was teaching 'Philosophy of mathematics'.

686. Leopold Gegenbauer (1849-1903)
• The Gegenbauer polynomials are solutions to the Gegenbauer differential equation and are generalizations of the associated Legendre polynomials.
• However, the name of Gegenbauer occurs in many other places, such as Gegenbauer functions, Gegenbauer transforms, Gegenbauer series, Fourier-Gegenbauer sums, Gauss-Gegenbauer quadrature, Gegenbauer's integral inequalities, Gegenbauer's partial differential operators, the Gegenbauer equation, Gegenbauer approximation, Gegenbauer weight functions, the Gegenbauer oscillator, and the Gegenbauer addition theorem published in 1875.

687. Helge Tverberg (1935-)
• Tverberg is familiar with this background, and moves deftly to prove a stronger characterisation by weakening the clearly technical assumption that the information function is continuous, defending this move with judicious dispatch: "If my weakening of the conditions is insignificant from an information-theoretic point of view, I do not think it is so from a purely mathematical one." The whole exercise only takes a couple of pages; and Tverberg's pioneering judgement has been amply confirmed - a survey 'The fundamental equation of information and its generalizations' by W Sander, in 1987 of generalisations of the functional equation satisfied by the information function ran to 108 references; and more recently a whole book 'Characterization of Information Measures' by B Ebanks, P Sahoo and W Sander (1998) has been devoted to the topic.

688. Maximilian Herzberger (1899-1982)
• Among his first papers written in English we mention: On the Fundamental Optical Invariant, the Optical Tetrality Principle, and on the New Development of Gaussian Optics Based on This Law (1935); On the Characteristic Function of Hamilton, the Eiconal of Bruns, and Their Use in Optics (1936); Hamilton's Characteristic Function and Bruns' Eiconal (1937); and Theory of Transversal Curves and the Connections Between the Calculus of Variations and the Theory of Partial Differential Equations (1938).
• The idea first came to Max in the mid-1940's and by 1954 he was finally able to demonstrate with mathematical equations that what the world had thought impossible was indeed theoretically possible.

689. Paul Ehrenfest (1880-1933)
• In 1917 and 1920 Ehrenfest published papers investigating the problem of the extent to which the three-dimensional nature of physical space is determined by the structure of basic physical equations or is reflected in these basic equations.

690. Eugenio Beltrami (1835-1900)
• Some of Beltrami's last work was on a mechanical interpretation of Maxwell's equations.
• (dated December, 1888) is devoted to the mechanical interpretation of Maxwell's equations.

691. Claude E Shannon (1916-2001)
• At the Massachusetts Institute of Technology he also worked on the differential analyser, an early type of mechanical computer developed by Vannevar Bush for obtaining numerical solutions to ordinary differential equations.
• The most important results [mostly given in the form of theorems with proofs] deal with conditions under which functions of one or more variables can be generated, and conditions under which ordinary differential equations can be solved.

692. Aryabhata (476-550)
• It also contains continued fractions, quadratic equations, sums of power series and a table of sines.
• This work is the first we are aware of which examines integer solutions to equations of the form by = ax + c and by = ax - c, where a, b, c are integers.

693. Robert Fricke (1861-1930)
• The present volume is a very attractive exposition of the modern theory of equations of degrees 5, 6, 7.
• Fricke's long experience with the latter subject made it easy for him to give a simple authoritative exposition of those portions of it which suffice for the transcendental solutions of equations of low degrees.

694. Leslie Woods (1922-2007)
• Woods own description of his 1953 paper The relaxation treatment of singular points in Poisson's equation states:- .
• If F is harmonic or is a solution to Poisson's equation, it may have singular points in the field or on the boundary at which it (a) has finite values, but has infinite derivatives, (b) has logarithmic infinities, or (c) has simple discontinuities.

695. Florimond de Beaune (1601-1652)
• Every trace of the work was lost until 1963, when it was rediscovered among manuscripts in the Roberval Archive at the Academie des Sciences in Paris, and thus it appears for the first time in the present critical edition (the book [',' R Schmidt and E Black (trans.), Francois Viete, Albert Girard, Florimond de Beaune, The early theory of equations: on their nature and constitution (Golden Hind Press, Fairfield, CT, 1986).','2]).
• The first from Costabel [',' R Schmidt and E Black (trans.), Francois Viete, Albert Girard, Florimond de Beaune, The early theory of equations: on their nature and constitution (Golden Hind Press, Fairfield, CT, 1986).','2]:- .

696. Robert Remak (1888-1942)
• these equations are very awkward to handle mathematically.
• There is, however, work in progress concerning the numerical solution of linear equations with several unknowns using electrical circuits.

697. Claude Berge (1926-2002)
• He then applied this symbolic calculus to combinatorial analysis, Bernoulli numbers, difference equations, differential equations and summability factors.

698. René Eugène Gateaux (1889-1914)
• He recalled that Volterra introduced this notion to study problems including an hereditary phenomenon, but also that it was used by others (Jacques Hadamard and Paul Levy) to study some problems of mathematical physics - such as the equilibrium problem of fitted elastic plates - finding a solution to equations with functional derivatives, or, in other words, by calculating a relation between this functional and its derivative.
• Though I am still mobilized, I work on lectures I should read at the College de France on the functions of lines and the equations with functional derivatives and at this occasion I would like to develop several chapters of the theory.

699. Johann Bernoulli (1667-1748)
• Integration to Bernoulli was simply viewed as the inverse operation to differentiation and with this approach he had great success in integrating differential equations.
• He summed series, and discovered addition theorems for trigonometric and hyperbolic functions using the differential equations they satisfy.

700. Thomas MacRobert (1884-1962)
• Its special features are an emphasis on geometrical methods, extensive discussion of special functions and second-order differential equations, and a profusion of illustrative examples.
• It is a very useful text-book on special functions, and an introduction to their application to partial differential equations of mathematical physics.

701. Piers Bohl (1865-1921)
• He graduated in 1887 with a degree in mathematics having won a Gold Medal for an essay he wrote on The Theory of Invariants of Linear Differential Equations in 1886.
• Bohl's doctoral dissertation applied topological methods to systems of differential equations.

702. Francisco José Duarte (1883-1972)
• He published papers on the general solution of a diophantine equation of the third degree x3 + y3 + z3 - 3xyz = v3, simplified Kummer's criterion and gave a simple proof of the impossibility of solving the Fermat equation x3 + y3 + z3 = 0 in nonzero integers.

703. Raoul Bott (1923-2005)
• We mentioned Smale above, and the second was Daniel Quillen who wrote his thesis Formal Properties of Over-Determined Systems Of Linear Partial Differential Equations at Harvard.
• The main themes of the papers included in [Volume 4] are the geometry and topology of the Yang-Mills equations and the rigidity phenomena of vector bundles.

704. Stefan Warschawski (1904-1989)
• The first was a single author paper On the solution of the Lichtenstein-Gershgorin integral equation in conformal mapping.
• Theory while the second, On the solution of the Lichtenstein-Gershgorin integral equation in conformal mapping.

• Volume 1 covers numbers, functions, limits, analytic geometry, algebra, set theory; volume 2 covers differential calculus, infinite series, elements of differential geometry and of function theory; and volume 3 covers integral calculus and its applications, function theory, differential equations.
• Friedrich Losch added a fourth volume in 1980 to cover more modern material: set theory, Lebesgue measure and integral, topological spaces, vector spaces, functional analysis, integral equations.

706. Mary Newson (1869-1959)
• She spoke to Klein while he was in the United States and he tested her to see if her understanding of mathematics, in particular of differential equations, was good enough to profit from doctoral studies.
• She completed her thesis Uber den Hermiteschen Fall der Lameschen Differentialgleichungen (On the Hermite case of the Lame differential equations) in the summer of 1896 and was examined in July 1896.

707. Charles Hutton (1737-1823)
• The first volume looks at topics such as: arithmetic including discussion of square and cube roots, arithmetical and geometrical progressions, compound interest, double position and permutations and combinations; logarithms; algebra including the study of quadratic equations and the Cardan-Tartaglia method for cubic equations; geometry which follows the approach in Euclid's Elements; surveying; and conic sections.

• Van Roomen had proposed a problem which involved solving an equation of degree 45 in Ideae mathematicae (1593).
• The formal object, however, is the equality (aequalitas) of quantities, since only those problems, in which some equation is either explicitly given or can be deduced from the data of the problem, are analytic.

709. Jean-Marie Duhamel (1797-1872)
• He published articles such as Sur les equations generales de la propagation de la chaleur dans les corps solides dont la conductibilite n'est pas la meme dans tous les sens Ⓣ (1832) and Sur la methode generale relative au mouvement de la chaleur dans les corps solides plonges dans des milieux dont la temperature varie avec le temps Ⓣ (1833) in the Journal of the Ecole Polytechnique.
• Duhamel worked on partial differential equations and applied his methods to the theory of heat, to rational mechanics, and to acoustics.
• 'Duhamel's principle' in partial differential equations arose from his contributions to the distribution of heat in a solid with a variable boundary temperature.

• In his first work as a student in 1950, he proved that the graph of a function f (x) of a real variable satisfying the functional equation f (x + y) = f (x) + f (y) and having discontinuities is dense in the plane.
• (Clearly, all continuous solutions of the equation are linear functions.) This result was not published at the time.

711. Hertha Marks Ayrton (1854-1923)
• Hertha's mathematical training was evident too, since not only did she conduct experiments but she was able to give an equation, now called the Ayrton equation, exhibiting a linear relation between arc length, pressure, and potential difference.

712. Giovanni Sansone (1888-1979)
• Sansone continued to undertake research in algebra and number theory, where he studied solutions of cubic equations over finite fields, but it was not a popular area of research in Italy at this time so eventually he moved towards undertaking research in analysis.
• Later he worked on differential geometry followed by work on series of orthogonal functions, and then moved to linear and nonlinear differential equations.

713. Cyril Offord (1906-2000)
• It was during these last three years at Cambridge that he worked with J E Littlewood on the topic for which he is best known today, and they published a series of important joint papers beginning with On the number of real roots of a random algebraic equation in 1938.
• In the following year they published a second paper with this title and in it they give estimates of the expected number of real roots for an equation of degree n when the coefficients are identically distributed random variables.

714. George G Lorentz (1910-2006)
• Kamke was writing a book on differential equations.
• I wrote some 20 papers: joint papers with Kamke and Knopp, papers related to differential equations, papers on summability, on Fourier series, and papers where rearrangements play a role.

• 4, of the auxiliary problem amounting to the solution by means of conics of the cubic equation (a - x) x2 = b c2.
• the solutions (a) by Diocles of the original problem of II.4 without bringing in the cubic, (b) by Dionysodorus of the auxiliary cubic equation.

716. Harald Cramér (1893-1985)
• One interesting paper by Cramer over this period which we should note is one he published in 1920 discussing prime number solutions x, y to the equation ax + by = c, where a, b, c are fixed integers.
• Note that if a = b = 1 then the question of whether this equation has a solution for all c is Goldbach's conjecture, while if a = 1, b = -1, c = 2, then the question about prime solutions to x = y + 2 is the twin prime conjecture.

717. John Mauchly (1907-1980)
• In particular the School used a Bush analyser, designed by Vannevar Bush specifically to integrate systems of ordinary differential equations.
• Von Neumann was working on this project and became involved with the ENIAC computer and used it to solve systems of partial differential equations which were crucial in the work on atomic weapons at Los Almos.

718. Edmund Hlawka (1916-2009)
• Ordnung Ⓣ (1937) was on linear differential equations of the second order.
• He has contributed to Diophantine approximation, the geometry of numbers, uniform distributions, analytic number theory, discrete geometry, convexity, numerical integration, inequalities, differential equations and gas dynamics.

719. Pedro Nunes (1502-1578)
• The book is in three parts, the first part dealing with equations of the first and second degree and the third part dealing with equations of the third degree.

720. Mary Cartwright (1900-1998)
• The Radio Research Board of the Department of Scientific and Industrial Research produced a memorandum regarding certain differential equations which came out of modelling radio and radar work.
• They began to collaborate studying the equations.

721. Alfred Loewy (1873-1935)
• Loewy worked on linear groups, the algebraic theory of differential equations and actuarial mathematics.
• He also published papers (in German) in the Transactions of the American Mathematical Society such as: On the reducibility of real groups of linear homogeneous substitutions (1903); On group theory, with applications to the theory of linear homogeneous differential equations (1904); and On completely reducible groups that belong to a group of linear homogeneous substitutions (1905).

722. Friedrich Karl Schmidt (1901-1977)
• Heffter, an expert on differential equations, complex analysis and analytic geometry, had been appointed to Freiburg in 1911 having previously been a full professor at RWTH Aachen and Kiel.
• Galois theory and algebraic equations; 6.

723. Mikhael Leonidovich Gromov (1943-)
• He did, however, contribute the text of his lecture A topological technique for the construction of solutions of differential equations and inequalities which was published in the Conference Proceedings in 1971.
• It has been emphasised above that he tends to look at all questions from the geometric side: he translates them in ad hoc geometric terms, and uses his extraordinary geometric intuition to investigate them thoroughly; it should be added that he is also able to treat, in the same way, questions coming from the most diverse branches of mathematics: algebra, analysis, differential equations, probability theory, theoretical physics, etc.

724. Max Dehn (1878-1952)
• I attended his course in 'Non-linear Partial Differential Equations'.
• I attended his course in Non-linear Partial Differential Equations.

725. Jozéf Hoëné Wronski (1778-1853)
• A piece of work which he had undertaken during this period resulted in a publication Resolution generale des equations de tous degres Ⓣ in 1812 claiming to show that every equation had an algebraic solution.
• For good measure, it contains a summary of the "general solution of the fifth degree equation".

726. Thomas Bromwich (1875-1929)
• Some of this work is described in [',' J D Zund and J M Wilkes, Bromwich’s method for solving the source-free Maxwell equations, Tensor (NS) 55 (2) (1994), 192-196.','6] where its history is explained:- .
• T J I'A Bromwich's method for solving the source-free Maxwell equations for electromagnetic waves.

727. Nicolas Chuquet (1445-1488)
• The sections on equations cover quadratic equations where he discusses two solutions.

728. Paul Lévy (1886-1971)
• Not only did Levy contribute to probability and functional analysis but he also worked on partial differential equations and series.
• He undertook a large-scale work on generalised differential equations in functional derivatives.

729. Christian Kramp (1760-1826)
• He published his memoir on double refraction Sur la double refraction de la chaux carbonatee Ⓣ in 1811 and, in 1820, he published Equations des nombres Ⓣ which contains a new approximate method to solve numerical equations.

730. Mikhail Fedorovich Subbotin (1893-1966)
• He had already published two papers prior to submitting his Master's thesis, one was On the determination of singular points of analytic functions while the second was published in France and was on singular points of certain differential equations.
• Later he worked in celestial mechanics producing new methods of calculating orbits from three observations based on solving the Euler-Lambert equations.

731. Thoralf Skolem (1887-1963)
• It was entitled Einige Satze uber ganzzahlige Losungen gewisser Gleichungen und Ungleichungen Ⓣ, and was on integral solutions of certain algebraic equations and inequalities.
• Skolem was remarkably productive publishing around 180 papers on topics such as Diophantine equations, mathematical logic, group theory, lattice theory and set theory.

732. Georges Reeb (1920-1993)
• Equations differentielles Ⓣ, written jointly with Robert Campbell, was a 78-page booklet published in 1964.
• It presented the theory of ordinary differential equations in a form which would prove useful to physicists and engineers.
• He explained the geometric approach to the theory of differential equations which he had adopted and indicated that it followed the approach begun by Henri Poincare, Paul Painleve and Elie Cartan.
• For example, at the Fourth International Colloquium on Differential Geometry at Santiago de Compostela in 1978 he gave the talk Equations differentielles et analyse non classique Ⓣ which surveyed results on the perturbation of dynamical systems obtained using methods of nonstandard analysis.

733. Ali Moustafa Mosharrafa (1898-1950)
• Report for the Session 1935-36.','14] reports that he read a paper to the Society on 30 March 1936 with title The Equations of Maxwell and a Variable Speed of Light.
• In his later years, he was occupied with the generalization of Einstein's equations, particularly with the study of the path of an electrically charged particle, a study which was published in 1948.

734. Thomas Fantet de Lagny (1660-1734)
• In about 1690 he developed a method of giving approximate solutions of algebraic equations and, in 1694, Halley published a twelve page paper in the Philosophical Transactions of the Royal Society giving his method of solving polynomial equations by successive approximation which is essentially the same as that given by Lagny a few years earlier.

735. Leopold Klug (1854-1945)
• All the way up to the solving of fourth order algebraic equations.
• And at the time of Euler, it was not known that the equations above the fourth order cannot be solved.

736. Simon Stevin (1548-1620)
• In the latter Stevin presented a unified treatment for solving quadratic equations and a method for finding approximate solutions to algebraic equations of all degrees.

737. Moshe Livsic (1917-2007)
• He was particularly interested in the courses in complex variable, integral equations and differential equations.

• He does not treat equations above the second degree except for ones which can easily be reduced to at most second degree equations followed by the extraction of roots.

739. Guglielmo Libri (1803-1869)
• A little-known consequence of these disputes is that Liouville made his famous announcement of Evariste Galois's important work on the theory of equations in response to an attack by Libri in 1843.
• However he made many contributions to number theory and to the theory of equations.

740. François Français (1768-1810)
• Francois worked on partial differential equations and his memoir of 1795 on this topic was developed further and presented to the Academie des Sciences in 1797.
• Lacroix praised Francais' work and described it as making a major contribution to the study of partial differential equations; however, it was not published.

741. James Mercer (1883-1932)
• Mercer was a mathematical analyst of originality and skill; he made noteworthy advances in the theory of integral equations, and especially in the theory of the expansion of arbitrary functions in series of orthogonal functions.
• Mercer's theorem about the uniform convergence of eigenfunction expansions for kernels of operators appears in his 1909 paper Functions of positive and negative types and their connection with the theory of integral equations published in the Philosophical Transactions.

742. Louis de Branges (1932-)
• The classical ingredients of the proof, the Loewner differential equation and the inequalities conjectured by Robertson and Milin, as well as the Askey-Gasper inequalities from the theory of special functions, are clearly described in the volume 'The Bieberbach Conjecture' (published by the American Mathematical Society).
• The key was to find norms for which the necessary inequalities could be propagated by the Loewner equation.

743. Cesare Arzelà (1847-1912)
• He had also worked on the theory of equations publishing the paper Sopra la teoria dell' eliminazione algebraica x Ⓣ in 1877.
• In the year long course of lectures Arzela proved that equations of degree greater than four cannot be solved by radicals.

744. Emil Grosswald (1912-1989)
• For the second edition of the text published in 1984, Grosswald had added material on L-functions and primes in arithmetic progressions, the arithmetic of number fields, and Diophantine equations.
• In Bessel polynomials Grosswald studies: the relationship between Bessel functions and Bessel polynomials, differential equations and differential recurrence relations satisfied by the generalized Bessel polynomials, recurrence relations satisfied by the generalized Bessel polynomials, orthogonality properties of the generalized Bessel polynomials and the corresponding moment problem, relations of the generalized Bessel polynomials and the classical orthogonal polynomials, generating functions, Rodrigues-type formulas, the generalized Bessel polynomials and continued fractions, the zeros of the Bessel polynomials, algebraic properties of the Bessel polynomials, and the Galois group of the Bessel polynomials.

745. Solomon Lefschetz (1884-1972)
• He tackled problems related to dissipative nonlinear ordinary differential equations but did not take the usual approach of using linear theory to tackle nonlinear differential equations.

746. Beniamino Segre (1903-1977)
• By 1931 when he was appointed to the Chair of Geometry at the University of Bologna he already had 40 publications in algebraic geometry, differential geometry, topology and differential equations.
• This was a period during which he made exceptional research contributions on algebraic geometry but his interests also broadened, stimulated by discussions with Mordell and Kurt Mahler, to diophantine equations and the arithmetic of algebraic varieties.

747. Neville Watson (1886-1965)
• Watson worked on a wide variety of topics, all within the area of complex variable theory, such as difference equations, differential equations, number theory and special functions.

748. Stefan Banach (1892-1945)
• However, an exception was made to allow him to submit On Operations on Abstract Sets and their Application to Integral Equations.
• The theory generalised the contributions made by Volterra, Fredholm and Hilbert on integral equations.

749. Yves Rocard (1903-1992)
• In this book, he opens with a readable account of the fundamentals of the kinetic theory of gases, and finds the usual equations of motion, and expressions for the viscosity for various molecular models.
• It is assumed that the reader has some facility in mathematics and thus is familiar with the common vector operations, simple manipulations with complex variables, linear differential equations, and series expansions.

750. Boris G Galerkin (1871-1945)
• His visits around European construction sites ended around 1914 but his academic work then turned to the area for which he is today best known, namely the method of approximate integration of differential equations known as the Galerkin method.
• Galerkin's important work on the finite element method is described in [',' G Fairweather, Finite Element Galerkin Methods for Differential Equations, Lecture Notes in Pure and Applied Mathematics (New York, 1978).','2] and [',' V Thomee, Galerkin Finite Element Methods for Parabolic Problems, Lecture Notes in Mathematics 1054 (New York, 1984).','3].

751. Edmond Laguerre (1834-1886)
• Laguerre studied approximation methods and is best remembered for the special functions the Laguerre polynomials which are solutions of the Laguerre differential equations.
• This memoir of Laguerre is significant not only because of the discovery of the Laguerre equations and polynomials and their properties, but also because it contains one of the earliest infinite continued fractions which was known to be convergent.

752. Kazimierz Zorawski (1866-1953)
• He spent time in Leipzig where he studied continuous groups of transformations now called Lie groups, and Gottingen where he studied differential equations.
• After returning to Krakow, Żorawski continued to teach courses on analytical and synthetic geometry, differential geometry, the formal theory of the differential equations, the theory of the forms, and the theory of the Lie groups.

753. Lajos Dávid (1881-1962)
• There were only a few to assist him at the Mathematics Seminar, so Lajos David himself held lectures on a very wide variety of topics: descriptive geometry, infinite series, infinitesimal calculus and geometry, analysis, the practical solution of equations, the theory of differential equations, surface theory, probability theory, and practical mathematics.

• This is a textbook on numerical methods for solving finite systems of linear equations, inverting matrices, and calculating the eigenvalues of finite matrices, all with desk calculators.
• The second chapter deals with numerical methods for the solution of systems of linear equations and the inversion of matrices, and the third with methods for computing characteristic roots and vectors of a matrix.

755. Pierre-Simon Girard (1765-1836)
• one may learn to find the equation for some solid as one finds the equation for a curved plane.

756. Pierre Fermat (1601-1665)
• Fermat posed further problems, namely that the sum of two cubes cannot be a cube (a special case of Fermat's Last Theorem which may indicate that by this time Fermat realised that his proof of the general result was incorrect), that there are exactly two integer solutions of x2 + 4 = y3 and that the equation x2 + 2 = y3 has only one integer solution.
• History Topics: Pell's equation .

757. Fred Hoyle (1915-2001)
• In 1945 he published On the integration of the equations determining the structure of a star which discussed the most advantageous way of integrating the equations of stellar equilibrium.

758. Ronald Graham (1935-)
• It took a knowledge of differential equations to solve it.
• He was a plenary speaker at the British Mathematical Colloquium in East Anglia in 1990 when he gave the lecture Arithmetic progressions: from Hilbert to Shelah and he was again a plenary speaker in 2009 in Galway when he gave the lecture The combinatorics of solving linear equations.

759. Alfréd Haar (1885-1933)
• He examined the standard systems of orthonormal trigonometric functions and also orthonormal systems related to Sturm-Liouville differential equations.
• After the work of his thesis, which we gave some details of above, he went on to study partial differential equations with applications to elasticity theory.

• Treated are: Nomograms for equations with two variables, with three variables (6 types), order and class of nomograms, nomograms with several variables, projective and homographic transformation of nomograms, classification of nomograms.
• He published papers such as the following written in Romanian: Two theorems concerning the separation of variables in nomography (1955); On rhomboidal nomograms (1956); The best projective transformation of the scales of alignment nomograms (1957); and Functional equations in connection with nomography (1958).

• However, he was led to an equation involving cubes, squares and numbers which he failed to solve after giving it lengthy meditation.
• Therefore, this solution was declared impossible until the appearance of Ja'far al-Khazin who solved the equation with the help of conic sections.

762. Guido Fubini (1879-1943)
• In this area he worked on differential equations, analytic functions and functions of several complex variables.
• Another analysis topic he studied was non-linear integral equations.

763. Aurel Angelescu (1886-1938)
• Aurel Angelescu's main fields of interest were generating functions for polynomials, linear differential equations, functional analysis, trigonometric series and the general theory of algebraic equations.

764. Lev Pontryagin (1908-1988)
• He began to study applied mathematics problems, in particular studying differential equations and control theory.
• Another book by Pontryagin Ordinary differential equations appeared in English translation, also in 1962.

• When she first reached Bryn Mawr College, Maddison continued to work on this topic but later, advised by Scott, she began to work on singular solutions of differential equations.
• in 1896 for her thesis On Singular Solutions of Differential Equations of the First Order in Two Variables and the Geometrical Properties of Certain Invariants and Covariants of Their Complete Primitives and in the same year appointed as Reader in Mathematics at Bryn Mawr.

766. Albert Wangerin (1844-1933)
• He taught many courses at the University of Halle including: linear partial differential equations; calculus of variations; theory of elliptical functions; synthetic geometry; hydrostatics and capillarity theory; theory of space curves and surfaces; analytic mechanics; potential theory and spherical harmonics; celestial mechanics; the theory of the map projections; hydrodynamics; and the partial differential equations of mathematical physics.

767. Ernest de Jonquières (1820-1901)
• He also worked on algebra, in particular the theory of equations, and, in the latter part of his life, on the theory of numbers where he examined Diophantine equations and the distribution of primes.

768. Charles Coulson (1910-1974)
• In almost every case the fundamental problem is the same, since it consists in solving the standard equation of wave motion; the various applications differ chiefly in the conditions imposed upon these solutions.
• Let us indicate the contents of the 156 page book: The equation of wave motion; Waves on strings; Waves in membranes; Longitudinal waves in bars and springs; Waves in liquids; Sound waves; Electric waves; General considerations.

769. Constantin Carathéodory (1873-1950)
• He added important results to the relationship between first order partial differential equations and the calculus of variations.
• Caratheodory wrote many fine books including Lectures on Real Functions (1918), Conformal representation (1932), Calculus of Variations and Partial Differential Equations (1935), Geometric Optics (1937), Real functions Vol.

770. Richard von Mises (1883-1953)
• His Institute rapidly became a centre for research into areas such as probability, statistics, numerical solutions of differential equations, elasticity and aerodynamics.
• He classified his own work, not long before his death, into eight areas: practical analysis, integral and differential equations, mechanics, hydrodynamics and aerodynamics, constructive geometry, probability calculus, statistics and philosophy.

771. James Eells (1926-2007)
• In it the whole geometry or topology of the spaces involved play a role, rather than just the equations describing the behaviour or motion in small areas.
• This he did with "Global Analysis" in 1971-72, "Geometry of the Laplace Operator" in 1976-77, and "Partial Differential Equations in Differential Geometry", in 1989-90.

772. Naonobu Ajima (1732-1798)
• Tsuda Nobuhisa solved the problem with an equation of degree 1024.
• Ajima's remarkable achievement was to reduce this to an equation of degree 10.

773. Clifford Ambrose Truesdell III (1919-2000)
• He took courses from Bateman on the partial differential equations of mathematical physics in 1940-41, and in 1941-42 on methods of mathematical physics (where for the entire year he and C-C Lin were the only students), aerodynamics of compressible fluids, and potential theory.
• In subject matter, in particular their coverage of continuum mechanics and physics, and their use of the theory of partial differential equations and special functions, the courses formed a solid foundation for the young researcher.

774. Marian Smoluchowski (1872-1917)
• He taught a variety of courses: potential theory, mechanics, electricity, optics, thermodynamics, kinetic theory of gases, differential equations, and mathematical physics.
• Smoluchowski made many contributions to physics and mathematics, particularly to the theory of Brownian motion, stochastic processes and related problems, of which the most important are the 'Smoluchowski equations' bearing his name.

775. Hermann Schubert (1848-1911)
• Algebraically, the solution of the problems of enumerative geometry amounts to finding the number of solutions for certain systems of algebraic equations with finitely many solutions.
• Since the direct algebraic solution of the problems is possible only in the simplest cases, mathematicians sought to transform the system of equations, by continuous variation of the constants involved, into a system for which the number of solutions could be determined more easily.

776. Gaetano Scorza (1876-1939)
• Now, Cassel profoundly observes that there is nothing in that event that is essentially characteristic of free competition, and therefore the reasoning by which this conclusion is drawn from the presence of the equations of maximum satisfaction in the system that determine the equilibrium, is nothing other than gross sophistry.
• The mathematician, who does not possess the general theory of what is called 'corpi numerici' knows, through algebra, the theory of equations; through number theory, the theory of congruencies with respect to a prime modulus; through the treatises on algebraic numbers, the theory of congruencies with respect to a prime ideal; three theories of which, even if he has spotted some analogy, he does not see the innermost bounds.

• In recent decades those spaces have been used in analysis, constructive theory of functions, differential equations, integral equations, probability, mathematical statistics, etc.

778. Olga Taussky-Todd (1906-1995)
• While in Gottingen Taussky also edited Artin's lectures in class field theory (1932), assisted Emmy Noether in her class field theory and Courant with his differential equations course.
• For the first time I realised the beauty of research on differential equations - something that my former boss, Professor Courant, had not been able to instil in me.

779. Lejeune Dirichlet (1805-1859)
• In 1852 he studied the problem of a sphere placed in an incompressible fluid, in the course of this investigation becoming the first person to integrate the hydrodynamic equations exactly.
• These series had been used previously by Fourier in solving differential equations.

780. Giorgio Bidone (1781-1839)
• He published Recherches sur la nature de la trascendante ∫ dx/log z Ⓣ (1809) and Methode pour reconnaitre le nombre de solutions qu'admet une equation trascendante a une seule inconnue Ⓣ (1809) in the Memoirs of the Academy of the Sciences of Turin.
• His research at this time was on the solution of transcendental equations and also on definite integrals with papers such as Sur diverses integrals definies Ⓣ (1813), in which he used the method of Mascheroni series to reduce various integrals to known cases, and Sur les transcendantes elliptiques Ⓣ (1818) in which he extended the work of Legendre on the numerical values of elliptic functions of the first and second kind.
• For example, in his study of overflow, after verifying by experimental means that the upstream propagation of an obstacle is accompanied by an increase in the water level, he established the shape of the liquid surface, and derived, by using pure mathematics, the equations for describing the expanse and height of the overflow.

781. Axel Thue (1863-1922)
• His contributions to the theory of Diophantine equations are discussed in [',' K E Aubert, Diofantiske likninger i norsk matematikk.
• In fact Thue wrote 35 papers on number theory, mostly on the theory of Diophantine equations, and these are reproduced in [',' T Nagell, A Selberg, S Selberg and K Thalberg (eds.), A Thue, Selected mathematical papers of Axel Thue, Introduction by Carl Ludwig Siegel (Universitetsforlaget, Oslo, 1977).','2].

782. Otton Nikodym (1887-1974)
• the Radon-Nikodym theorem and derivative, the Nikodym convergence theorem, the Nikodym-Grothendieck boundedness theorem), in functional analysis (the Radon-Nikodym property of a Banach space, the Frechet-Nikodym metric space, a Nikodym set), projections onto convex sets with applications to Dirichlet problem, generalized solutions of differential equations, descriptive set theory and the foundations of quantum mechanics.
• Some of his other books were: Introduction to differential calculus, (Warsaw, 1936) (jointly with his wife), Theory of tensors with applications to geometry and mathematical physics, I, (Warsaw, 1938), Differential Equations, (Poznań, 1949).

783. Tom Apostol (1923-2016)
• Apostol also took Zuckerman's number theory course, Clyde Myron Cramlet's differential equations course, Thomas McFarlane's complex variable course, and Roy Martin Winger's projective geometry course.
• He sat in on a course on differential equations given by Norman Levinson, which was excellent, but gave up on a course on Fourier analysis by Norbert Wiener who he said was a terrible lecturer.

784. Vijay Patodi (1945-1976)
• His doctoral thesis, Heat equation and the index of elliptic operators, was supervised by M S Narasimhan and S Ramanan and the degree was awarded by the University of Bombay in 1971.
• An analytic approach, via the heat equation yields easily a formula for the index of an elliptic operator on a compact manifold: but, the formula involves an integrand containing too many derivatives of the symbol, while from the Atiyah-Singer index theorem one would expect only two derivatives to figure.

785. Atle Selberg (1917-2007)
• Atle taught himself methods of solving equations by reading the books in his father's library.
• He would have remained in Oslo to undertake his doctoral research but the library was poor so he went to Uppsala where he attended lectures by Trygve Nagell (1895-1988) who worked on Diophantine equations.

786. Ettore Bortolotti (1866-1947)
• In the 1940 paper on Babylonian mathematics, Bortolotti gives a summary of problems published by Neugebauer but argues that the fact that large series of examples for quadratic equations are made up from the same roots demonstrates that this pair of roots has an 'arcane mystic property'.
• It is also wrong to deny the existence of approximations to irrational square roots, to assume a geometrical basis of the quadratic equations or to deny the existence of texts of this type in the Hellenistic period.

787. John McCowan (1863-1900)
• A regular attendee at meetings of the Edinburgh Mathematical Society, he presented the papers: On a representation of elliptic integrals by curvilinear arcs (12 June 1891); On the solution of non-linear partial differential equations of the second order (13 May 1892); and Note on the solution of partial differential equations by the method of reciprocation (11 November 1892).

788. Abraham Wald (1902-1950)
• seasonal corrections to time series, approximate formulas for economic index numbers, indifference surfaces, the existence and uniqueness of solutions of extended forms of the Walrasian system of equations of production, the Cournot duopoly problem, and finally, in his much used work written with Mann (1943), stochastic difference equations.

789. Glenny Smeal (1890-1974)
• Among Smeals' publications are (with Ernest Frederick John Love) The psychrometric formula (1911), (with S Brodetsky) On Graeffe's method for complex roots of algebraic equations (1924) and The equations of the gravitational field in orthogonal coordinates (1926).

790. Max Abraham (1875-1922)
• He loved his absolute aether, his field equations, his rigid electron just as a youth loves his first flame, whose memory no later experience can extinguish.

791. Edgar Raymond Lorch (1907-1990)
• In a series of remarkable memoirs, Liouville demonstrated the impossibility of evaluating certain indefinite integrals, and of solving certain differential equations, in terms of elementary functions.

792. Frantisek Wolf (1904-1989)
• Consideration of the Schrodinger equation leads to perturbation problems for partial differential operators, where the change may occur in the coefficients of the operator or in boundary conditions.

793. Luigi Bianchi (1856-1928)
• Bianchi partial differential equations play an important role.

794. William Trail (1746-1831)
• His widely used Elements of Algebra, which he published for his students in 1770, ranged from first principles to equations of all orders and included applications to problem solving, physics and geometry.

795. Hellmuth Kneser (1898-1973)
• For example he produced a beautiful solution to the functional equation f ( f (x) ) = ex which he published in 1950, and the deep understanding he achieved of the strange properties of manifolds without a countable basis of neighbourhoods between 1958 and 1964.

• Gopel linked four more of these quadratics through a homogeneous fourth degree relation, later named the 'Gopel relation' which coincides with the equation of the Kummer surface.

797. Hermann Bondi (1919-2005)
• The exact relativistic form of the equation of hydrostatic support by an isotropic pressure is found in an especially convenient form.

798. Karl Weierstrass (1815-1897)
• ., from the differential equation defining this function, was the first mathematical task I set myself; and its fortunate solution made me determined to devote myself wholly to mathematics; I made this decision in my seventh semester ..

799. Douglas Hartree (1897-1958)
• However Niels Bohr gave a lecture course in Cambridge in 1921 and Hartree was much influenced, working on applications of numerical methods for integrating differential equations to calculate atomic wave functions.

800. Gordon Whyburn (1904-1969)
• His research was mostly on second order ordinary differential equations, see [',' W T Reid, William M Whyburn 1901-1972, ','3] for details.

• This system led to much work on integer solutions of equations and their application to astronomy.

802. Leonard Dickson (1874-1954)
• Dickson: Theory of Equations .

• in 1971 for his thesis A Study of Some Systems of Linear and Quasilinear Elliptical Partial Differential Equations.

804. Abraham Plessner (1900-1961)
• Then in the winter seminar of session 1921/22, he studied in at the University of Berlin where Richard von Mises lectured on differential and integral equations and Ludwig Bieberbach on differential geometry.

• And then we apply in a new situation, in this case in the situation of algebraic equations which is purely algebraic.

806. Hjalmar Mellin (1854-1933)
• He also extended his transform to several variables and applied it to the solution of partial differential equations.

807. Eduard Heine (1821-1881)
• Before arriving at Halle, Heine published on partial differential equations and during his first few years teaching at Halle he wrote papers on the theory of heat, summation of series, continued fractions and elliptic functions.

808. Charles Augustin Coulomb (1736-1806)
• From examination of many physical parameters, he developed a series of two-term equations, the first term a constant and the second term varying with time, normal force, velocity, or other parameters.

809. Hermann Schwarz (1843-1921)
• An idea from this work, in which he constructed a function using successive approximations, led Emile Picard to his existence proof for solutions of differential equations.

810. Steve Rallis (1942-2012)
• This allows one to determine the analytic continuation and functional equation of these L-functions, as well as their explicit poles.

811. Karl Heinrich Weise (1909-1990)
• In years soon after the war Weise published a small but concise book Gewohnliche Differentialgleichungen Ⓣ (1948) in which he discusses Legendre, Bessel, and Sturm-Liouville equations.

812. Clarence Lewis (1883-1964)
• After a good resume of the classical theory of equations and inequations, he proceeds to a parallel development of the foundations of the logic of propositions, propositional functions, and classes on the Boole-Peirce-Schroder basis and on that of the 'Principia', exhibiting both the formal identity of the two systems and the inadequacy of Peirce's enumerative method of defining universal and particular propositions in terms respectively of iterated logical multiplication and iterated logical addition.

813. Bartel van der Waerden (1903-1996)
• In Galois theory he showed the asymptotic result that almost all integral algebraic equations have the full symmetric group as Galois group.

814. Ulisse Dini (1845-1918)
• In this last work he devoted a chapter to integral equations in which he presented many of his own innovative ideas.

815. Pierre Duhem (1861-1916)
• It is to this reading, to these exchanges of views, that I owe the greater part of my later works, almost all of which deal with the calculus of variations, the theory of Hugoniot, hyperbolic partial differential equations, Huygens' principle.

816. Guido Ascoli (1887-1957)
• Between 1926 and 1930 he published twelve important works on partial differential equations: these include Sul problema di Dirichlet nei campi sferici e ipersferici Ⓣ (1927); Sulle singolarita isolate delle funzioni armoniche Ⓣ (1928); Sull'unicita della soluzione nel problema di Dirichlet Ⓣ (1928); and Sull'equazione di Laplace dello spazio iperbolico Ⓣ (1929).

817. Katherine Johnson (1918-)
• We created the equations needed to track a vehicle in space.

818. Xu Guang-qi (1562-1633)
• The brilliant "tian yuan" or "coefficient array method" or "method of the celestial unknown" for solving equations which had been expounded with such skill by Li Zhi in the 13th century was no longer understood in China.

819. Gottlob Frege (1848-1925)
• He lectured on all branches of mathematics, in particular analytic geometry, calculus, differential equations, and mechanics, although his mathematical publications outside the field of logic are few.

820. Gilbert Bliss (1876-1951)
• They were An existence theorem for a differential equation of the second order, with an application to the calculus of variations and Sufficient condition for a minimum with respect to one-sided variations.

821. Franz Mertens (1840-1927)
• Mertens is perhaps best known for his determination of the sign of Gauss sums, his work on the irreducibility of the cyclotomic equation, and the hypothesis which bears his name.

822. August Möbius (1790-1868)
• He avoided the army and completed his Habilitation thesis on Trigonometrical equations.

823. Pauline Sperry (1885-1967)
• Wilczynski had begun his research career as a mathematical astronomer but his study of the dynamics of astronomical objects had turned his interests towards differential equations and then to projective differential geometry and ruled surfaces.

824. Heinz Prüfer (1896-1934)
• In it Prufer gives a very simple proof of an expansion theorem for a particular second order linear homogeneous differential equation coming from the oscillation and evolution theorem.

825. John Campbell (1862-1924)
• In a paper published two years later "On the Theory of Simultaneous Partial Differential Equations" he develops a system of formulas by which it may be determined whether such a system is or is not integrable.

826. Gaspard-Gustave de Coriolis (1792-1843)
• It is not the ideas of 'work' for which Coriolis is best remembered, however, rather it is for the Coriolis force which appears in the paper Sur les equations du mouvement relatif des systemes de corps Ⓣ (1835).
• He showed that the laws of motion could be used in a rotating frame of reference if an extra force called the Coriolis acceleration is added to the equations of motion.

827. Aleksandr Aleksandrov (1912-1999)
• These first three works were all as a result of his mathematical work with Delone but also in 1934 he published two physics papers on quantum mechanics On the calculation of the energy of a bivalent atom by Fok's method and Remark on the commutation rule in Schrodinger's equation.

828. Samarendra Nath Roy (1906-1964)
• This work led to partial differential equations which could only be solved numerically, but at this time the Applied Mathematics Department had no computing facilities.

829. Alfreds Meders (1873-1944)
• Adolf Kneser, who had been taught by Kronecker and written a thesis on algebraic functions and equations, was the professor at Dorpat.

• He began this work in 1851 when elected as President of the Royal Astronomical Society and he presented a paper to the Royal Society in 1853 in which he showed that Laplace had omitted terms from his equations which were not negligible.

831. Seth Ward (1617-1689)
• Arithmetic and geometry are sincerely and profoundly taught, analytical algebra, the solution and application of equations, containing the whole mystery of both those sciences, being faithfully expounded in the Schools by the Professor of Geometry, and in several Colleges by particular tutors.

832. Vincenzo Flauti (1782-1863)
• The latter, towards which he was particularly hostile, going as far as stating that all it consisted of was simply establishing the "equations of condition", relative to what one wanted to treat, and to make use of them by combining them conveniently.

833. Charles Weatherburn (1884-1974)
• Among these twenty, we also mention: Singular parameter values in the boundary problems of the potential theory (1914); Vector integral equations and Gibbs' dyadics (1916); On the hydrodynamics of relativity (1917); Some theorems in four-dimensional analysis (1917); and Green's dyadics in the theory of elasticity (1923).

834. Hans Grauert (1930-2011)
• Much space is occupied by the treatment of systems of linear equations (the Gaussian algorithm), the theory of determinants and the theory of eigenvalues of linear mappings in 'Euclidean' vector spaces (transformation of principal axes).

835. Kuo-Tsai Chen (1923-1987)
• An outstanding and original mathematician, Chen's work falls naturally into three periods: his early work on group theory and links in the three sphere; his subsequent work on formal differential equations, which gradually developed into his most powerful and important work; and his work on iterated integrals and homotopy theory, which occupied him for the last twenty years of his life.

836. Benjamin Osgood Peirce (1854-1914)
• master of the methods dealing with the partial differential equations of mathematical physics.

837. Yewande Olubummo (1960-)
• Precalculus I, II, Calculus I, II, III, Linear Algebra I, II, Foundations of Mathematics, Differential Equations, Abstract Algebra I, Real Variables I, II.

• We only know details of the Handy Tables through the commentary by Theon of Alexandria but in [',' B van Dalen, On Ptolemy’s table for the equation of time, Centaurus 37 (2) (1994), 97-153.','76] the author shows that care is required since Theon was not fully aware of Ptolemy's procedures.

• Smirnov was a very active member of this circle, for example lecturing on the theory of algebraic equations, particularly the work of Goursat and Appell.

840. Nikolai Fuss (1755-1826)
• Most of Fuss's papers are solutions to problems posed by Euler on spherical geometry, trigonometry, series, differential geometry and differential equations.

841. Oscar Schlömilch (1823-1901)
• Conics are treated at first individually and in detail so as to bring out particular geometrical properties; then, starting with the equation of the second degree, they are discussed and reduced to their simplest forms and incidentally, as it were, we are introduced to the general properties of the curves of the second and higher orders.

842. Henry Baker (1866-1956)
• Its contents are as follows: Euclid's theory of parallel lines; Propositions of incidence; The symbolic representation and Pappus's theorem; Theorems proved from the propositions of incidence; The fundamental hypothesis; The symbols of the real points of a line; Involution and harmonic ranges; Related ranges and pencils; Conics; Assignment of two absolute points, properties of circles; The parabola; The rectangular hyperbola; Theorems on conics; Length and distance; Equation of conic and line.

843. Charles Tinseau (1748-1822)
• Tinseau wrote on the theory of surfaces, working out the equation of a tangent plane at a point on a surface, and he generalised Pythagoras's theorem proving that the square of a plane area is equal to the sum of the squares of the projections of the area onto mutually perpendicular planes.

844. Oliver Kellogg (1878-1932)
• In 1908 he published three papers, namely Potential functions on the boundary of their regions of definition and Double distributions and the Dirichlet problem, both in the Transactions of the American Mathematical Society, and A necessary condition that all the roots of an algebraic equation be real in the Annals of Mathematics.

845. Carl Johannes Thomae (1840-1921)
• He also discovered methods of solving difference equations giving solutions in the form of definite integrals.

846. Joan Sylvia Lyttle Birman (1927-)
• The particular problems that are suggested by braids have led me to knot theory, to operator algebras, to mapping class groups, to singularity theory, to contact topology, to complexity theory and even to ordinary differential equations and chaos.

847. Leopold Vietoris (1891-2002)
• Another of his papers published during the war was Zur Kennzeichnung des Sinus und verwandter Funktionen durch Funktionalgleichungen Ⓣ (1944) in which he developed a method to introduce the sine by a functional equation.

• Thus, although applications (e.g., to rigid body dynamics and elasticity theory) are mentioned and the usual matrix theory is covered (including, e.g., reduction to the Jordan canonical form), there is none of the standard material on the solution of systems of linear equations.

849. Theodor Kaluza (1885-1954)
• Kaluza is remembered for this in Kaluza-Klein (named after the mathematician Oskar Klein) field theory, which involved field equations in five-dimensional space.

850. Leonard Jimmie Savage (1917-1971)
• His grades began to improve: C in analytic geometry; B in calculus; B in differential equations; A in Raymond Wilder's foundations of mathematics; and A in Raymond Wilder's point set topology course.

851. Emanuel Sperner (1905-1980)
• The first chapter deals with affine space and linear equations.

• Hippocrates' book also included geometrical solutions to quadratic equations and included early methods of integration.

853. Salomon Bochner (1899-1982)
• He also published papers on the gamma function, the zeta function and partial differential equations.

854. Georgios Remoundos (1878-1928)
• The first of these, in April 1908, was the International Congress of Mathematicians held in Rome where he delivered the paper Sur les zeros des integrales d'une classe d'equations differentielles Ⓣ in the Analysis Section.
• He also lectured at this meeting, presenting Sur les singularites des equations differentielles Ⓣ.
• Let us look briefly at the mathematical areas on which Remoundos worked which largely focused on Mathematical Analysis and especially on its two fundamental branches, namely: Theory of Functions and Theory of Differential Equations.

855. Anneli Lax (1922-1999)
• The title was On Cauchy's Problem for Partial Differential Equations with Multiple Characteristics, and it was published in Communications on Pure and Applied Mathematics in 1956.

856. Eric Temple Bell (1883-1960)
• Even complicated set-ups in problems by Lagrange's equations don't bother him in the least ..

857. George Lusztig (1946-)
• The thesis was published under the same title in the Journal of Differential Equations in 1972.

858. Julius Weingarten (1836-1910)
• In this work he reduced the problem of finding all surfaces isometric to a given surface to the problem of determining all solutions to a partial differential equation of the Monge-Ampere type.

859. Ugo Morin (1901-1968)
• Several of the mathematicians at Padua were very active opponents of Fascism, including Eugenio Curiel (1912-1945), who had been appointed assistant professor of rational mechanics in February 1934, Ernesto Laura (1879-1949), the professor of rational mechanics from 1922 and director of the mathematics seminar, and Giuseppe Zwirner (1904-1979), who worked on ordinary differential equations and was very active in the anti-Fascist Giustizia e Liberta movement.

860. Georg Hamel (1877-1954)
• He wrote papers on differential equations, and on fluid dynamics, for example on the critical velocity of a fluid, that is the velocity at which the flow changes from laminar to turbulent.

861. John Pople (1925-2004)
• He read about the differential and integral calculus, teaching himself how to solve differential equations.

862. Paul Appell (1855-1930)
• He then wrote on algebraic functions, differential equations and complex analysis.

863. Arnold Walfisz (1892-1962)
• Walfisz published further monographs: Pell's equation (Russian) (1952); Lattice points in many-dimensional spheres (Russian) (1960); and Weylsche Exponentialsummen in der neueren Zahlentheorie Ⓣ (1963).

864. Finlay Freundlich (1885-1964)
• His occasional inability to comprehend these ideas had the salutary effect of making Einstein seek to simplify their mathematical formulation, for if one of Felix Klein's pupils could not make sense of his equations who could? Through his intimate contact with Einstein, Freundlich was the first to become thoroughly acquainted with the fundamental principles of the new gravitational theory and, as Einstein himself remarks in the foreword of Freundlich's book, he was particularly well qualified as its exponent because he had been the first to attempt to put it to the test.

865. John Dougall (1867-1960)
• Examples of papers he read at meeting of the Society are Elementary Proof of the Collinearity of the Mid Points of the Diagonals of a Complete Quadrilateral on Friday 12 February 1897; Methods of Solution of the Equations of Elasticity on 10 December 1897; and Notes on Spherical Harmonics on 12 December 1913.

866. Oskar Perron (1880-1975)
• However he also worked on differential equations, matrices and other topics in algebra, continued fractions, geometry and number theory.

867. Jean Delsarte (1903-1968)
• He worked during that year at the private mansion of the Foundation, undertaking research for his doctoral thesis and also working on his first two papers Sur les rotations dans l'espace fonctionnel Ⓣ and Etude de certaines equations integrales qui generalisent celles de Fredholm Ⓣ which were published by the Academy of Science.
• At Nancy he developed a new course on differential equations in the academic year 1933-34 and in the following year, also at Nancy, he gave a course on Riemann spaces and relativity.
• He published a series of papers on this topic in 1934-35: Les fonctions moyenne-periodiques Ⓣ (1934); Application de la theorie des fonctions moyenne-periodiques a la resolution de certaines equations integrales Ⓣ (1934); Application de la theorie des fonctions moyenne-periodiques a la resolution des equations de Fredholm-Norlund Ⓣ (1935); and Les fonctions moyenne-periodiques Ⓣ (1935).

868. Erich Kähler (1906-2000)
• He submitted his habilitation thesis on the integrals of algebraic differential equations to Hamburg in 1930 and became a Privatdozent.

869. Klaus Fuchs (1911-1988)
• He also published On the Invariance of Quantized Field Equations (1938/39), On the Stability of Nuclei Against -Emission (1939) and (with Born) On Fluctuations in Electromagnetic Radiation (1939).

870. Stanley Jevons (1835-1882)
• The 'logical piano', a machine designed by Jevons and constructed by a Salford watchmaker, had 21 keys for operations in equational logic.

• He noted the impossibility of giving an integer solution to the equation .

872. Nathan Fine (1916-1994)
• Fine writes from the viewpoint of a number theorist, and his slim volume is rich with examples and results from the theory of partitions, the study of Ramanujan's mock theta functions, and modular equations.

873. Charles Loewner (1893-1968)
• We should also note that Loewner's proof uses the Loewner differential equation which has been studied extensively since he introduced it, and was used by de Branges in his celebrated proof of the Bieberbach conjecture.

874. Marshall Stone (1903-1989)
• His doctorate was awarded in 1926 for a thesis entitled Ordinary Linear Homogeneous Differential Equations of Order n and the Related Expansion Problems.

875. Herman Chernoff (1923-)
• He took courses by Bers, Feller, Loewner, Tamarkin, and others, and wrote a Master's dissertation Complex Solutions of Partial Differential Equations under Bergman's supervision.

876. Daniel Hecht (1777-1833)
• His later texts covered topics such as quadratic and cubic equations, differential and integral calculus, and arithmetic and geometry.

877. Wenceslaus Johann Gustav Karsten (1732-1787)
• He wrote an important article in 1768 Von den Logarithmen vermeinter Grossen Ⓣ in which he discussed logarithms of negative and imaginary numbers, giving a geometric interpretation of logarithms of complex numbers as hyperbolic sectors, based on the similarity of the equations of the circle and of the equilateral hyperbola.

878. Felice Casorati (1835-1890)
• Differential equations were of great interest to him and his research in this area was undertaken with the aim of making the existing theories more accurate and more complete.

• In Mahasiddhanta Aryabhata II gives in about twenty verses detailed rules to solve the indeterminate equation: by = ax + c.

880. David Picken (1879-1956)
• He read papers to the Society such as A Proof of the Addition Theorem in Trigonometry to the meeting on Friday 9 December 1904, On a Direct Method of Obtaining the Foci and Directrices from the General Equation of the Second Degree to the meeting on 9 June 1905, On Simson Line and Related Theory: and An Exercise in Geometric Generality (communicated by A W Young) on 8 May 1914.

881. Benjamin Peirce (1809-1880)
• For example An Elementary Treatise on Plane Trigonometry (1835), First Part of an Elementary Treatise on Spherical Trigonometry (1836), An Elementary Treatise on Sound (1836), An Elementary Treatise on Algebra : To which are added Exponential Equations and Logarithms (1837), An Elementary Treatise on Plane and Solid Geometry (1837), An Elementary Treatise on Plane and Spherical Trigonometry (1840), and An Elementary Treatise on Curves, Functions, and Forces Vol 1 (1841), Vol 2 (1846).

882. Timothy Pedley (1942-)
• The variation of its overall radiusnanwith time may be predicted from the vertical impulse equation, and it should be possible to make the same prediction by equating the rate of loss of combined kinetic and potential energy to the rate of viscous dissipation.

883. Pavel Urysohn (1898-1924)
• At this stage Urysohn was interested in analysis, in particular integral equations, and this was the topic of his habilitation.

884. Ruth Gentry (1862-1917)
• During the years she taught there, Vassar College offered graduate level course, which included "advanced courses on projective geometry, differential equations, and modern methods of analytics.

885. Mary Taylor (1898-1984)
• There she carried out research on her specialist topics of the magneto-ionic theory of radio wave propagation and also in differential equation, particularly their applications to physics.

886. Phillip Griffiths (1938-)
• Though the papers selected cover a broad range of topics in complex analysis, algebraic geometry and differential equations ..

887. Ernst Schröder (1841-1902)
• Schroder's concept of solving a relational equation was a precursor of Skolem functions, and he inspired Lowenheim's formulation and proof of the famous theorem that every sentence with an infinite model has a countable model, the first real theorem of modern logic.

888. Leonard Gillman (1917-2009)
• Next he took courses on Integral Calculus, Matrix Theory, and Differential Equations.

889. Enoch Beery Seitz (1846-1883)
• Find the equation to the locus of the centres of all the circles that can be incribed in a given semi-ellipse.

890. Louis Poinsot (1777-1859)
• In addition Poinsot worked on number theory and on this topic he studied Diophantine equations, how to express numbers as the difference of two squares and primitive roots.

891. Alexander Animalu (1938-)
• 4.2 Einstein's Field Equation and its Complement .

892. Demetrios Kappos (1904-1985)
• These were the texts (i) Lectures on Analysis.nInfinitesimal Calculus (ii) nLectures on Analysis.nTheory of Complex Functions (iii) Lectures on Analysis.nDifferential Equations (iv) Introduction to algebra.

893. Arthur Erdélyi (1908-1977)
• He also worked on asymptotic analysis, fractional integration and singular partial differential equations.

894. Ferdinand von Lindemann (1852-1939)
• He is famed for his proof that π is transcendental, that is, π is not the root of any algebraic equation with rational coefficients.

895. Mark Kac (1914-1984)
• in the summer of 1930 I became obsessed with the problem of solving cubic equations.

896. Yudell Luke (1918-1983)
• His work on these topics led him to require much information on special functions and he was led to develop tables of special functions and to use numerical techniques to solve equations.

897. Ludolph Van Ceulen (1540-1610)
• In 1595 the two men competed in the solution of a forty-fifth degree equation proposed by van Roomen in his 'Ideae mathematicae' (1593) and recognised its relation to the expression of sin 45A in terms of sin A.

• It deals with the development into a continued fraction of the generating function of a sequence satisfying a difference equation.

899. Li Shanlan (1811-1882)
• The "tian yuan" or "coefficient array method" or "method of the celestial unknown" of setting up equations, which Li learnt from Li Zhi's famous text, had a huge influence on him and he began to push these algebraic techniques forward solving a whole variety of new problems.

900. Joseph Walsh (1895-1973)
• The topics he taught, rotating them from year to year, included calculus, algebra, mechanics, differential equations, complex variable, probability, number theory, potential theory, approximation theory, and function theory.

901. Georg Sidler (1831-1907)
• He attended lectures by J Bertrand (analysis), M Chasles (geometry), H Faye (astronomy), G Lame (mathematical physics), U J Le Verrier (popular astronomy), J Liouville (differential equations) and V Puiseux (celestial mechanics).

• Two years later he again defended a thesis at Dorpat, this time on the Gauss equation, and was promoted to assistant professor.
• For example: An outline of the Cracovian algorithms of the method of least squares (1942); On the accuracy of least squares solution (1945); Sur la resolution des equations normales de la methode des moindres carres Ⓣ (1948); Sur l'interpolation dans le cas des intervalles inegaux Ⓣ (1949); A general least squares interpolation formula (1949); Les cracoviens et quelques-unes de leurs applications en geodesie Ⓣ (1949); On the general least squares interpolation formula (1950); and Resolution d'un systeme d'equations lineaires algebriques par division Ⓣ (written much earlier by only published in 1951 due to World War II) [',' J Witkowski, Biography in Dictionary of Scientific Biography (New York 1970-1990).','1]:- .

903. John Charles Fields (1863-1932)
• After the award of the degree in 1887 for his thesis Symbolic Finite Solutions, and Solutions by Definite Integrals of the Equation (dn/dxn)y - (xm)y = 0, he remained teaching at Johns Hopkins for a further two years.

904. Alfred Barnard Basset (1854-1930)
• The treatment of Plucker's equations is specially striking, and equally unsatisfactory; the author would, in fact, have done better to have omitted his first four chapters and given a reference to Salmon's work in the preface.

• He wrote on additive number theory (lattice points, partitions, Waring's problem), analysis, Bernoulli numbers, class invariants, definite integrals, elliptic integrals, infinite series, the Weierstrass approximation theorem), analytic number theory (Dirichlet L-functions, primes, Riemann and Epstein zeta functions), binary quadratic forms and class numbers, combinatorial problems (block designs, difference sets, Latin squares), Diophantine equations and Diophantine approximation, elementary number theory (arithmetic functions, continued fractions, and Ramanujan's tau function), and exponential and character sums (Gauss sums, Kloosterman sums, trigonometric sums).

906. Émile Clapeyron (1799-1864)
• The Clapeyron relation, a differential equation which determines the heat of vaporisation of a liquid, is named after him.

907. Heinrich Schröter (1829-1892)
• He attended courses by Dirichlet on number theory and on differential equations which influenced Schroter's teaching for the whole of his career but it was Steiner who was a major influence on Schroter's research.

908. Jorgen Gram (1850-1916)
• Gram later published this work in the Journal fur Mathematik and it proved to be of fundamental importance in the development of the theory of integral equations.

909. Andrew Young (1891-1968)
• He read the paper On the quasi-periodic solutions of Mathieu's differential equation to the Society at its meeting on Friday 13 February 1914.

910. William Prager (1903-1980)
• The numerical methods aspect also shows the hand of a master and covers all the material that is usually given in a one term course, including ordinary differential equations, in a reasonably rigorous and at the same time practical manner.

911. Hubert Linfoot (1905-1982)
• In fact despite still being an undergraduate, Linfoot was already undertaking research and published his first paper The domains of convergence of Kummer's solutions to the Riemann P-equation in 1926.

912. Heinrich Burkhardt (1861-1914)
• Other topics on which Burkhardt published papers included groups, differential equations, differential geometry and mathematical physics.

• In Chapter 8 he looks at simultaneous linear equations and computes with both positive and negative numbers.

914. Charles Babbage (1791-1871)
• He wrote two major papers on functional equations in 1815 and 1816.

915. Li Rui (1768-1817)
• In 1813 while working on his edition of the lost work by Yang Hui, Li Rui wrote the Kai Fang Shuo (Theory of Equations of Higher Degree).

916. Boris Nikolaevich Delone (1890-1980)
• He studied Tschirnhaus's inverse problem, producing methods to determine whether or not two given cubic equations determine the same field.

917. Lloyd Williams (1888-1976)
• In 1925 Cox was awarded his doctorate by Cornell University for his thesis Polynomial solutions of difference equations.

918. Frenicle de Bessy (about 1604-1674)
• History Topics: Pell's equation .

919. John Torrence Tate (1925-)
• In his thesis, which has become a classic, he proved the functional equation for Hecke's L-series by a novel method involving Fourier analysis on idele groups.

920. Karl Schwarzschild (1873-1916)
• Schwarzschild's relativity papers give the first exact solution of Einstein's general gravitational equations, giving an understanding of the geometry of space near a point mass.

921. Nicola Fergola (1753-1824)
• He did learn some mathematics from Giuseppe Marzucco (1713-1800) but this was only up to quadratic equations.

922. Dénes König (1884-1944)
• It includes not only popular puzzling arithmetic problems including riddles which usually can be solved with linear equations, but also more remarkable works which were printed in foreign countries as mentioned above, and which lead us into the wonderful world of the numbers.

923. Achille-Pierre Dionis du Séjour (1734-1794)
• Dionis du Sejour also worked on the theory of equations, not attaining the depth of results of Bezout or Lagrange.

• He generalised a method of finding square roots and cube roots to finding nth roots, for n > 3, and then extended the method to solving polynomial equations of arbitrary degree.

925. Isaac Todhunter (1820-1884)
• He also wrote some more elementary texts, for example Algebra (1858), Trigonometry (1859), Theory of Equations (1861), Euclid (1862), Mechanics (1867) and Mensuration (1869).

926. Argelia Velez-Rodriguez (1936-)
• Her doctoral work consisted of studying differential equations which arose in the study of astronomical orbits.

927. August Crelle (1780-1855)
• Crelle realised the importance of Abel's work and published several articles by him in this first volume, including his proof of the insolubility of the quintic equation by radicals.

928. Herbert Robbins (1915-2001)
• Robbins' paper with his student Sutton Monro on Stochastic Approximation provided an analogue of an iterative method due to Isaac Newton for finding the root of a function, even when the function's equation is unknown and the evaluation of the function involves experimental error.

929. Ibn Yunus (950-1009)
• For example in [',' D A King, A double-argument table for the lunar equation attributed to Ibn Yunus, Centaurus 18 (1973/74), 129-146.','9] the author writes:- .

930. Forest Ray Moulton (1872-1952)
• His books include An Introduction to Celestial Mechanics (1902), An introduction to astronomy (1906), Descriptive astronomy (1912), Periodic orbits (1920) The Nature of the World and Man (1926), Differential equations (1930), Astronomy (1931), and Consider the Heavens (1935).

931. Cristoforo Alasia (1864-1918)
• In addition, when it is a question of a point or a straight, he has given its representation according to the method of Grassmann; and for circles and conics he has given the equation in barycentric or normal coordinates.

• For example, he communicated On Spheroidal Harmonics and Allied Functions, by Mr G B Jeffery to the meeting on Friday 11 June 1915 and Transformations of Axes for Whittaker's Solution of Laplace's Equation, by Dr G B Jeffery to the meeting on Friday 9 March 1917.

933. Isaac Newton (1643-1727)
• [Newton] brought me the other day some papers, wherein he set down methods of calculating the dimensions of magnitudes like that of Mr Mercator concerning the hyperbola, but very general; as also of resolving equations; which I suppose will please you; and I shall send you them by the next.

934. Jean-Pierre Serre (1926-)
• Serre's lecture was entitled "Prime numbers, equations and modular forms".

• The general linear equation was solved in the Apastamba's Sulbasutra.

936. Gheorghe Vrnceanu (1900-1979)
• Other topics he studied include the absolute differential calculus of congruences, analytical mechanics, partial differential equations of the second order, non-holonomic unitary theory, conformal connection spaces, metrics in spherical and projective spaces, Lie groups, global differential geometry, discrete groups of affine connection spaces, locally Euclidean connection spaces, Riemannian spaces of constant connection, differentiable varieties, embedding of lens spaces into Euclidean space, tangent vectors of spheres and exotic spheres, the equivalence method, non-linear connection spaces, and the geometry of mechanical systems.

937. Yitz Herstein (1923-1988)
• Among the methods and problems discussed in some detail are a derivation of the Slutsky equation via the calculus, a problem in Welfare Economics treated by the theory of convex sets, matrix theory as applied to international trade, and a game-theoretical approach to the personnel assignment problem.

938. Jakob Rosanes (1842-1922)
• he scribbled equations which his students never quite saw because as he wrote he hid them with his body and as he moved along he rubbed them out with his sponge.

939. Philip Stein (1890-1974)
• Rosenberg was interested in problems in numerical analysis and their collaboration led to their joint paper On the solution of linear simultaneous equations by iteration (1948).

940. Harold Davenport (1907-1969)
• At the most advanced level he wrote a monograph Analytic methods for Diophantine equations and Diophantine inequalities (1962) which includes many of his contributions extending the Hardy-Littlewood method.

941. George Airy (1801-1892)
• This text was one of eleven books which Airy published, some of the others being Trigonometry (1825), Gravitation (1834), and Partial differential equations (1866).

942. William Niven (1842-1917)
• In the present state of our knowledge of the resistance of the air to shot, the problem of integrating the equations of motion of the shot and of plotting-out a representation of the curve described by it is peculiar, because, according to the best experiments we possess, the law of the retardation cannot be expressed by a single exact formula which is available for the solution.

943. J Watt Butters (1863-1946)
• He also contributed to the mathematical work of the Society, For example at the meeting of the Society on Friday 11 January 1889, J Watt Butters discussed the solution of an algebraic equation.

944. Emil Post (1897-1954)
• thesis was on mathematical logic, and we shall discuss it further in a moment, but first let us note that Post wrote a second paper as a postgraduate, which was published before his first paper, and this was a short work on the functional equation of the gamma function.

945. George Mathews (1861-1922)
• Mathews also wrote Algebraic equations (1907) which is a clear exposition of Galois theory, and Projective geometry (1914).

946. Jacob T Schwartz (1930-2009)
• The present volume I under review contains the topological theory of spaces and operators, and the spectral theory of "arbitrary" operators and some applications; the second volume will contain the spectral theory of completely reducible operators and further applications, e.g., applications to differential operators and partial differential equations.

947. François Cosserat (1852-1914)
• The most practical results concerning elasticity were the introduction of the systematic use of the movable trihedral and the proposal and resolution, before Fredholm's studies, of the functional equations of the sphere and ellipsoid.

948. Francis Macaulay (1862-1937)
• What ideas were there then in this work? The main theme underlying the book is the problem of solving equations of systems of polynomials in several variables.

949. Rolf Nevanlinna (1895-1980)
• For example he wrote the paper Calculus of variation and partial differential equations (1967).

950. Gyula Farkas (1847-1930)
• In 1881 Gyula Farkas published a paper on Farkas Bolyai's iterative solution to the trinomial equation, making a careful study of the convergence of the algorithm.

951. Keith Stewartson (1925-1983)
• Keith Stewartson's abiding passion in mathematical research lay in the solution of the equations governing the motion of liquids and gases, and in the comparison of his theoretical predictions with experiment and observation.

952. Werner Romberg (1909-2003)
• In this work they investigated the hydrodynamical equations for an ideal incompressible fluid on a rotating sphere which is subjected to the influence of tidal forces.

953. Hans Bethe (1906-2005)
• Oddly, though, he left the neutrino out of the proton-proton reaction equation.

954. George Uhlenbeck (1900-1988)
• He extended Boltzmann's equation to dense gasses and wrote two important papers on Brownian motion.

955. Max Newman (1897-1984)
• The first was an early inroad on Hilbert's Fifth Problem, in which he proved that abelian continuous groups do not have arbitrarily small subgroups, the second was a simplified proof of a difficult fixed point theorem of Cartwright and Littlewood arising in the study of differential equations.

956. Niels Nielsen (1865-1931)
• He turned to number theory and studied Bernoulli numbers in Traite elementaire des nombres de Bernoulli Ⓣ (Gauthier-Villars, Paris, 1923) and Fermat's equation writing good textbooks on these topics.

957. Volker Strassen (1936-)
• Using this new matrix multiplication routine, Strassen was able to show that Gaussian elimination (an efficient algorithm for solving systems of linear equations) is not an optimal solution.

958. Henry Watson (1827-1903)
• In addition to these books he wrote on Lagrange's method and Monge's method for solving partial differential equations and, jointly with Galton, he wrote On the probability of extinction of families.

959. Eduard Wiltheiss (1855-1900)
• His doctoral studies on systems of hyperelliptic differential equations were supervised by Weierstrass and he submitted his thesis Die Umkehrung einer Gruppe von Systemen allgemeiner hyperelliptischer Differentialgleichungen Ⓣ to the University of Berlin.

960. Alfred Kempe (1849-1922)
• Kempe was taught mathematics by Cayley and graduated in 1872 with distinction in mathematics and in the same year he published his first mathematical paper A general method of solving equations of the nth degree by mechanical means.

961. Paul Cohn (1924-2006)
• His second book Linear equations was published in 1958 and another book Solid geometry was published in 1961.

962. Luigi Cremona (1830-1903)
• The geometric method is principally a use of terms or descriptive relations instead of equations.

963. Tom Whiteside (1932-2008)
• 1 - 14, especially 10 where he uses a proto-Lagrangian analysis to deduce a third-order defining differential equation).

964. Paul Dirac (1902-1984)
• Also in 1928 he found a connection between relativity and quantum mechanics, his famous spin-1/2 Dirac equation.

965. Arne Beurling (1905-1986)
• Beurling worked on the theory of generalized functions, differential equation, harmonic analysis, Dirichlet series and potential theory.

966. Luis Antonio Santaló (1911-2001)
• Esteban Terrades (1883-1950) had been appointed to the chair of Differential Equations in Madrid in 1932.

967. Loo-Keng Hua (1910-1985)
• Hua wrote several papers with H S Vandiver on the solution of equations in finite fields and with I Reiner on automorphisms of classical groups.

968. Alexander Dinghas (1908-1974)
• His work is in many areas of mathematics including differential equations, functions of a complex variable, functions of several complex variables, measure theory and differential geometry.

969. Anton Kazimirovich Suschkevich (1889-1961)
• Examples of courses he attended at this stage in his career are: Determinants, by Frobenius in the summer of 1908; Algebra I and Algebra II by Frobenius in 1908-09; Ordinary differential equations, by Schur in the summer of 1909; Chebyshev's Theorem, by Frobenius in November 1909; Bernoulli numbers by Frobenius in the summer of 1910, and Matrices, by Frobenius in the winter of 1910-11.

• Other mathematical results presented by Jyesthadeva include topics studied by earlier Indian mathematicians such as integer solutions of systems of first degree equation solved by the kuttaka method, and rules of finding the sines and the cosines of the sum and difference of two angles.

971. August Gutzmer (1860-1924)
• Among the advanced courses he taught we list: ordinary differential equations, analytic mechanics, calculus of variations, number theory, higher algebra, function theory and the theory of algebraic curves.

972. Arthur Conway (1875-1950)
• The first of these papers extended work of Love on electromagnetic waves in an isotropic medium while the next two concerned equations of classical electromagnetic field theory.

973. David Blackwell (1919-2010)
• The most interesting thing I remember from calculus was Newton's method for solving equations.

974. Ludwig Prandtl (1875-1953)
• On the contrary, Prandtl's own way to tackle the Navier-Stokes equations was to toy with flows far beyond the range of practical application, showing the pleasure and also the marvelling observation of a child, till a phenomenon crystallized that asked for explanation.

975. John Kemeny (1926-1992)
• There were many long calculations, deriving one formula from another to solve a differential equation.

976. André-Marie Ampère (1775-1836)
• In mathematics he worked on partial differential equations, producing a classification which he presented to the Institut in 1814.

977. Evelyn Boyd Granville (1924-)
• from Yale, Granville spent a postdoctoral year at the New York University Institute of Mathematics working on differential equations with Fritz John.

978. Moshé Flato (1937-1998)
• The second is the cohomological study of nonlinear representations of covariance groups of nonlinear partial differential equations which leads to important mathematical developments with nontrivial physical consequences ..

979. Jan Kalicki (1922-1953)
• Kalicki worked on logical matrices and equational logic and published 13 papers on these topics from 1948 until his death five years later.

980. Soraya Sherif (1934-)
• Sherif certainly returned to the College for Girls, Ain Shams University, for in 2014 she was named as the first supervisor of the thesis Solutions of Dynamic Equations by Nesreen Abd El Hamed Abd El Hameed Yaseen submitted to the Department of Mathematics, University College for Girls, Ain Shams University for a Ph.

• He published the lectures that he gave there, his book on Integral Calculus Curso teorico practico de calculo integral aplicado a la fisica y tecnica Ⓣ appearing in 1947 and his book on Differential Equations Curso teorico practico de ecuaciones diferenciales a la fisica y tecnica Ⓣ in 1950.

982. Edmond Halley (1656-1742)
• Halley's other activities included studying archaeology, geophysics, the history of astronomy, and the solution of polynomial equations.

983. Constantin Le Paige (1852-1929)
• Some of these papers were on topics he had worked on before he settled on geometry as his main interest, for example there are papers on continued fractions, differential equations, the difference calculus, and Bernoulli numbers.

984. Svetlana Jitomirskaya (1966-)
• He travelled all night to see me, only to have to wait for another three hours since I didn't want to miss a lecture on differential equations by Vladimir Igorevich Arnold.

985. Wang Yuan (1930-)
• However he did write a number of books such as: (with Hua Loo Keng) Applications of number theory to numerical analysis (1978); Goldbach Conjecture (1984); (with Hua Loo Keng) Popularising mathematical methods in the People's Republic of China (1989); Diophantine equations and inequalities in algebraic number fields (1991); (with Fang Kai-Tai) Number theoretic methods in statistics (1994); Hua Loo Keng (1995); and (with Fong Yuen) Calculus (1997).

986. Gotthold Eisenstein (1823-1852)
• While in Ireland in 1843 Eisenstein met Hamilton in Dublin, a city he would have dearly liked to have settled in, and Hamilton gave him a copy of a paper that he had written on Abel's work on the impossibility of solving quintic equations.

987. Patrick Moran (1917-1988)
• In 1939 he took courses: M H A Newman on topology, A S Besicovitch on integration, F Smithies on integral equations, J C Burkill on the theory of real functions, W W Rogosinski on Fourier series, and G U Yule on statistics.

988. Raymond Brink (1890-1973)
• Finally we give some examples of Brink's papers: A new integral test for the convergence and divergence of infinite series (1918); A new sequence of integral tests for the convergence and divergence of infinite series (1919); The May Meeting of the Minnesota Section (1927); Recent Publications: Reviews: Studies in the History of Statistical Method - With Special Reference to Certain Education Problems (1929); The May Meeting of the Minnesota Section (1930); A Simplified Integral Test for the Convergence of Infinite Series (1931); Recent Publications: Reviews: Differential Equations (1932); The Annual Meeting of the Minnesota Section (1937); College Mathematics During Reconstruction (1944), and A Course in Mathematics for the Purpose of General Education (1947).

989. George Green (1793-1841)
• The formula connecting surface and volume integrals, now known as Green's theorem, was introduced in the work, as was "Green's function" the concept now extensively used in the solution of partial differential equations.

990. Aleksei Kostrikin (1929-2000)
• The meaning of an algebraic concept can be of a number-theoretic or geometric nature, and frequently its roots lie in computational aspects of mathematics and in the solution of equations.

991. Tobias Mayer (1723-1762)
• with respect to the inequalities of motions, from that famous theory of the great Newton, which that eminent mathematician Eulerus first elegantly reduced to general analytic equations.

• For example they solved equations such as a (a - x) = x2 by geometrical means.

993. Eugene Paul Wigner (1902-1995)
• epoch-making work on how symmetry is implemented in quantum mechanics, the determination of all the irreducible unitary representations of the Poincare group, and his work with Bargmann on realizing those irreducible unitary representations as the Hilbert spaces of solutions of relativistic wave equations, ..

994. Sylvestre Lacroix (1765-1843)
• Not only did Monge use his influence to obtain this position for Lacroix, but he also acted as his mathematical advisor, recommending that he undertake research on partial differential equations and the calculus of variations.

995. Jordanus Nemorarius (1225-1260)
• In De numeris datis Jordanus gives results on solving quadratic equations similar to those given by al-Khwarizmi except general forms are given rather than the numerical examples of the earlier text.

996. Irving John Good (1916-2009)
• Quickly realising that the calculation would never terminate, he found rational approximations from Pell's equation x2 - 2y2 = 1, discovering this method for himself.

• (eds.), Harmonic Analysis, Partial Differential Equations, Complex Analysis, Banach Spaces, and Operator Theory 1, Association for Women in Mathematics Series 4 (Springer International Publishing, Switzerland, 2016), 3-24.','14]):- .

998. Alexander Weinstein (1897-1979)
• In examining singular partial differential equations he introduced a new branch of potential theory and applied the results to many different situations including flow about a wedge, flow around lenses and flow around spindles.

999. François-Joseph Servois (1768-1847)
• Servois worked in projective geometry, functional equations and complex numbers.

1000. Erich Hecke (1887-1947)
• Schoeneberg describes Hecke's contributions to a number of topics which he lists as follows: Hilbert modular functions, Dedekind zeta functions, arithmetical notions and methods, elliptic modular forms of level N, algebraic functions, Dirichlet series with functional equation, Hecke-operators Tn, and physics where he made contributions to the kinetic theory of gases.

1001. Hendrik de Vries (1867-1954)
• Gustav de Vries is the de Vries of the Korteweg-de Vries equation and has a biography in this archive.

1002. John Hellins (1749-1827)
• Hellins published many papers; the following were all in the Philosophical Transactions of the Royal Society: A new method of finding the equal roots of an equation by division (1782); Dr Halley's method of computing the quadrature of the circle improved; being a transformation of his series for that purpose, to others which converge by the powers of 60 (1794); Mr Jones' computation of the hyperbolic logarithm of 10 compared (1796); A method of computing the value of a slowly converging series, of which all the terms are affirmative (1798); An improved solution of a problem in physical astronomy, by which swiftly converging series are obtained, which are useful in computing the perturbations of the motions of the Earth, Mars, and Venus, by their mutual attraction (1798); A second appendix to the improved solution of a problem in physical astronomy (1800); and On the rectification of the conic sections (1802).

1003. Francesco Maurolico (1494-1575)
• Demonstratio algebrae, which is an elementary text looking at quadratic equations and problems whose solution reduces to solving a quadratic; .

1004. G de B Robinson (1906-1992)
• His early papers include: Note on an equation of quantitative substitutional analysis (1935) and On the fundamental region of an orthogonal representation of a finite group (1937).

1005. Yuri Ivanovich Manin (1937-)
• He has written papers on: algebraic geometry including ones on the Mordell conjecture for function fields and a joint paper with V Iskovskikh on the counter-example to the Luroth problem; number theory including ones about torsion points on elliptic curves, p-adic modular forms, and on rational points on Fano varieties; and differential equations and mathematical physics including ones on string theory and quantum groups.

1006. Eduard Helly (1884-1943)
• His thesis was on Fredholm equations.

1007. Ebenezer Cunningham (1881-1977)
• He wrote on linear differential equations, prompted by Pearson's work and other work related to statistics.

1008. Johann(III) Bernoulli (1744-1807)
• In the field of mathematics he worked on probability, recurring decimals and the theory of equations.

1009. Richard Fuchs (1873-1944)
• During these years, busy with the release of the publications of his father, he promoted his life's work, the theory of linear differential equations in the complex domain, through its own investigations, and a wide readership benefited from his ability present a clear presentation and a simple argument.
• These publications include Sur quelques equations differentielles lineaires du second ordre Ⓣ (1905), Uber lineare homogene Differentialgleichungen dritter Ordnung mit nur wesentlichen singularen Stellen Ⓣ (1906), Uber lineare homogene Differentialgleichungen zweiter Ordnung mit drei im Endlichen gelegenen wesentlich singularen Stellen Ⓣ (1907) and Uber elliptische Funktionen und Integrale in ihrer Abhangigkeit von einem Parameter Ⓣ (1908).

1010. Cornelius Lanczos (1893-1974)
• He worked on relativity theory and after writing his dissertation Relation of Maxwell's Aether Equations to Functional Theory he sent a copy to Einstein.

• It was the first operational program-controlled calculating machine and was used by the German aircraft industry to solve systems of simultaneous equations and other mathematical systems which were produced by the problems of dealing with the vibration of airframes put under stress.

1012. Johannes Widman (1462-1498)
• Widman used Cossist notation, as was usual at that time, discussing 24 different types of equations.

1013. Eliakim Moore (1862-1932)
• Other topics he worked on include algebraic geometry, number theory and integral equations.

1014. Thomas Bond Sprague (1830-1920)
• In addition, he published eight pure mathematical papers: [',' T B Sprague, On the nature of the curves whose intersections give the imaginary roots of an algebraic equation, Transactions of Royal Society of Edinburgh 30 (1882), 467-480.','16] and [',' T B Sprague, On a new algebra, by means of which permutations can be transformed in a variety of ways, and their properties investigated, Transactions of Royal Society of Edinburgh 37 (1893), 399-411.','17] in the Transactions of the Royal Society of Edinburgh and six papers in the Proceedings of the Edinburgh Mathematical Society: [',' T B Sprague, Note on the evaluation of functions of the form 00, Edinburgh Mathematical Society (1884).','18],[',' T B Sprague, On the different possible non-linear arrangements of eight men on a chess board, Edinburgh Mathematical Society (1889).','19], [',' T B Sprague, On the transformation and classification of permutations, Edinburgh Mathematical Society (1890).','20], [',' T B Sprague, On the geometrical interpretation of ii, Edinburgh Mathematical Society (1893).','21], [',' T B Sprague, On the eight Queens’ problem, Edinburgh Mathematical Society (1899).','22] and [',' T B Sprague, On the singular points of plane curves, Edinburgh Mathematical Society (1902).','23].

1015. Irmgard Flügge-Lotz (1903-1974)
• Here she applied her mathematical skills in solving differential equations to solve an important problem on the distribution of lift on wings (one that Prandtl himself had been unable to solve).

1016. Leopold Schmetterer (1919-2004)
• was mostly concerned with differential equations in the field of aerodynamics.

1017. Marjorie Senechal (1939-)
• While in Tucson she completed the work and submitted her thesis Approximate Functional Equations and Probabilistic Inner Product Spaces to the Illinois Institute of Technology and was awarded a Ph.D.

1018. Douglas Northcott (1916-2005)
• In particular he was taught to solve simultaneous equations and prove elementary theorems in Euclidean geometry which gave him a love of mathematics at this early stage in his education.

1019. Georg Faber (1877-1966)
• Only in the 1980s was Faber's idea seen to be an important ingredient for the efficient solution of partial differential equations.

1020. Pierre-Louis Moreau de Maupertuis (1698-1759)
• By 1731 he had written his first paper on astronomy and another on differential equations, and was rapidly developing a reputation as an all round mathematician and scientist.

1021. Samuel Roberts (1827-1913)
• In theory of numbers he was interested in the Pellian equation and similar problems.

1022. Johann Karl Burckhardt (1773-1825)
• After this the instructor should teach algebra up to and including equations of the second degree.

1023. Max Noether (1844-1921)
• This result showed that given two algebraic curves f (x, y) = 0, g(x, y) = 0 which intersect in a finite number of isolated points, then the equation of an algebraic curve which passes through all those points of intersection can be expressed in the form af + bg = 0, where a and b are polynomials in x and y, is and only if certain conditions are satisfied.

1024. John T Graves (1806-1870)
• As an aside, we note that Degen was the mathematician to whom the young Niels Henrik Abel submitted his "solution" of the quintic equation.

1025. George Pólya (1887-1985)
• He also worked on conformal mappings and potential theory, and he was led to study boundary value problems for partial differential equations and the theory of various functionals connected with them.

1026. Karl Feuerbach (1800-1834)
• one day he appeared in class with a drawn sword and threatened to cut off the head of every student in the class who could not solve the equations he had written on the blackboard.

1027. Timofei Fedorovic Osipovsky (1765-1832)
• His most famous work was the three-volume handbook A Course of Mathematics (1801-1823) which covered function theory, differential equations, and the calculus of variations.

1028. Howard Aiken (1900-1973)
• These plans were made for a very specific purpose, for Aiken's research had led to a system of differential equations which had no exact solution and which could only be solved using numerical techniques.

1029. Giulio Fagnano (1682-1766)
• Fagnano suggested new methods of solving equations of degree 2, 3 and 4.

1030. Hermann Ludwig Schmid (1908-1956)
• Following his move to Berlin, the direction of Schmid's research changed somewhat and he moved away from algebraic number theory, becoming interested in topics in algebraic geometry and Lame differential equations.

1031. Pierre Fatou (1878-1929)
• Fatou did not lose out completely, however, and even though he had not entered for the prize, the Academie des Sciences gave him an award for his outstanding 280-page paper on the topic, Sur les equations fonctionnelles Ⓣ published in 1920.
• Using existence theorems for the solutions to differential equations, Fatou was able to prove rigorously certain results on planetary orbits which Gauss had suggested but only verified with an intuitive argument.
• We should also mention his work on permutable functions Sur l'iteration analytique et sur les substitutions permutables Ⓣ (1923-24), one major paper Substitutions analytiques et equations fonctionnelles a deux variables Ⓣ on iterating functions of two complex variables, published in 1924, as well as ten further papers on iterating functions of a complex variable.

1032. John Herivel (1918-2011)
• II (1955) and The derivation of the equations of motion of an ideal fluid by Hamilton's principle (1955).

1033. Edward McShane (1904-1989)
• McShane is famous for his work in the calculus of variations, Moore-Smith theory of limits, the theory of the integral, stochastic differential equations, and ballistics.

1034. Lai-Sang Young (1952-)
• It is generally regarded as a study of the iteration of maps, of time evolution of differential equations, and of group actions on manifolds.

1035. Nikolai Evgrafovich Kochin (1901-1944)
• Kochin also edited the works of Ivan Aleksandrovich Lappo-Danilevskii (1896-1931), who was an expert on applying matrix theory to differential equations, and of Aleksandr Mikhailovich Lyapunov.

1036. Sydney Goldstein (1903-1989)
• He studied numerical solutions to steady-flow laminar boundary-layer equations in 1930.

1037. Edwin Elliott (1851-1937)
• All ageing mathematicians should be particularly pleased to learn that a second piece of work by Elliott, which was again of major importance, was his contribution to the theory of integral equations which he made after he retired.

1038. Howard Percy Robertson (1903-1961)
• Around this time he built on de Sitter's solution of the equations of general relativity in an empty universe and developed what are now called Robertson-Walker spaces [',' J L Greenstein : January 27, 1903 - August 26, 1961, Biographical Memoirs National Academy of Sciences 51 (1980), 343-361.','2]:- .

1039. Daniel Rutherford (1906-1966)
• Rutherford's papers in the 1940s included On the relations between the numbers of standard tableaux, On the matrix representation of complex symbols, On substitutional equations, Some continuant determinants arising in physics and chemistry, On commuting matrices and commutative algebras; these being published either by the Edinburgh Mathematical Society or by the Royal Society of Edinburgh.

1040. John Polkinghorne (1930-)
• Also in 1955 he published Temporally ordered graphs and bound state equations and On the classification of fundamental particles.

1041. Gino Fano (1871-1952)
• Early studies deal with line geometry and linear differential equations with algebraic coefficients ..

1042. Farkas Bolyai (1775-1856)
• For example he gave iterative procedures to solve equations which he then proved convergent by showing them to be monotonically increasing and bounded above.

1043. Kurt Hensel (1861-1941)
• He showed, at least for quadratic forms, that an equation has a rational solution if and only if it has a solution in the p-adic numbers for each prime p and a solution in the reals.

1044. Richard Dedekind (1831-1916)
• He attended courses by Dirichlet on the theory of numbers, on potential theory, on definite integrals, and on partial differential equations.

1045. Edward Routh (1831-1907)
• In fact the impact of this prize winning work was very significant since Thomson and Tait rewrote for the second edition of their text Natural philosophy treatise the part dealing with equations of motion using Routh's developments.

1046. Wilhelm Flügge (1904-1990)
• Unsymmetrical deformations are analysed to a considerable extent by means of the author's own system of basic equations.

1047. Florian Cajori (1859-1930)
• Before looking at his main work on the history of mathematics, let us first note that he did write some textbooks which were not historical texts such as An introduction to the modern theory of equations (1904) and Elementary algebra: First year course (1915).

1048. Ahmes (1680 BC-1620 BC)
• The Verso has 87 problems on the four operations, solution of equations, progressions, volumes of granaries, the two-thirds rule etc.

1049. John Machin (1680-1751)
• Machin had explained to Taylor in Child's Coffeehouse how to use Newton's series to solve Kepler's problem and also how Halley's method finds roots of polynomial equations.

1050. Nicolai Vasilievich Bugaev (1837-1903)
• He wrote on algebraic integrals of certain differential equations.

1051. William Oughter Lonie (1822-1894)
• Topics taught in Lonie's Mathematics Department in 1879 are: Mathematics - Euclid, Elementary Modern Geometry and Conic Sections, Plane and Spherical Trigonometry, with practice, Elementary Algebra with Higher Equations, Mensuration, and Mechanics; Physics - after Balfour Stewart and Modern Views of Natural Forces including Energy, Sound, Heat, Light; Geography - Modern Geography.

1052. Sergei Chernikov (1912-1987)
• There are properties such as solubility, a concept which goes back to Galois and attempts to classify which polynomial equations could be solved by radicals, which make perfect sense for infinite groups.

• His first paper On the roots of algebraic equations was published in 1921 and in the following year he published his first paper on conformal mappings.

1054. Wilhelm Magnus (1907-1990)
• In addition to research in group theory and special functions, he worked on problems in mathematical physics, including electromagnetic theory and applications of the wave equation.

1055. J Presper Eckert (1919-1995)
• Von Neumann was working on this project and became involved with the ENIAC computer and used it to solve systems of partial differential equations which were crucial in the work on atomic weapons at Los Almos.

1056. Gyula Vályi (1855-1913)
• His doctoral dissertation was on the theory of the propeller which led to his developing a theory of partial differential equations of the second order.

1057. Shiing-shen Chern (1911-2004)
• Principal among these are: Geometric structures and their equivalence problems; Integral geometry; Euclidean differential geometry; Minimal surfaces and minimal submanifolds; Holomorphic maps; Webs; Exterior Differential Systems and Partial Differential Equations; The Gauss-Bonnet Theorem; and Characteristic classes.

1058. Józef Marcinkiewicz (1910-1940)
• For in the field of real variable Marcinkiewicz had exceptionally strong intuition and technique, and the results he obtained in the theory of conjugate functions, had they been extended to functions of several variables might have given (as we see clearly now) a strong push to the theory of partial differential equations.

1059. Leo Moser (1921-1970)
• These include On the sum of digits of powers (1947), Some equations involving Euler's totient (1949), Linked rods and continued fractions (1949), On the danger of induction (1949) and A theorem on the distribution of primes (1949).

1060. Mina Rees (1902-1997)
• In 1931 Rees graduated with her doctorate for a thesis entitled Division algebras associated with an equation whose group has four generators.

1061. Theodor Reye (1838-1919)
• While undertaking research at Gottingen, he had attended inspiring lectures on partial differential equations by Bernhard Riemann.

1062. Aleksandr Mikhailovich Lyapunov (1857-1918)
• (4) (1993), 3-47.','8] include: stability, particularly the stability of critical points; the construction and the application of the Lyapunov function; stability of functional- differential equations; the second Lyapunov method; and the method of the Lyapunov vector function in stability theory and nonlinear analysis.

1063. André Weil (1906-1998)
• At this time he was particularly fascinated by solving Diophantine equations.

1064. Grigori Yakovlevich Perelman (1966-)
• A possible approach to attacking the Poincare Conjecture had been developed by Richard Hamilton who had introduced a significant idea in 1982 when he began to study a particular equation he called the Ricci flow.

1065. Luigi Menabrea (1809-1896)
• The principle of Menabrea states that the elastic energy of a body in perfect elastic equilibrium is a minimum with respect to any possible system of stress-variation compatible with the equations of the statics of continua in addition to the boundary conditions.

1066. Christiaan Huygens (1629-1695)
• History Topics: Quadratic, cubic and quartic equations .

1067. Ernst Lindelöf (1870-1946)
• Lindelof's first work in 1890 was on the existence of solutions for differential equations.

1068. Shokichi Iyanaga (1906-2006)
• Although it was this latter topic which would eventually attract Iyanaga, at this stage of his undergraduate career he was attracted to differential equations.

1069. Edwin Spanier (1921-1996)
• Interestingly, one of Spanier's theories, now called Alexander-Spanier homology, is currently being applied to analyse differential equations - a return to Poincare's original use of algebraic topology.

1070. James Stirling (1692-1770)
• In the minutes of a meeting of the Royal Society of London on 4 April 1717, when Brook Taylor lectured on extracting roots of equations and on logarithms, it is recorded:- .

1071. Mark Krein (1907-1989)
• During this time he worked on topics such as Banach spaces, the moment problem, integral equations and matrices, and on spectral theory for linear operators.

1072. Udo Wegner (1902-June1989)
• In 1928 Wegner, in collaboration with Findlay Freundlich and Eberhard Hopf, published On the integral equation for radiative equilibrium in the Monthly Notices of the Royal Astronomical Society.

• The systems of diophantine equations studied by these methods and the flows of lattice points introduced by these methods are closely related to the behaviour of the ideal classes of the corresponding algebraic fields.

1074. Paul Turán (1910-1976)
• Their importance first of all is that they lead to interesting deep problems of a completely new type; they have quite unexpectedly surprising consequences in many branches of mathematics - differential equations, numerical algebra, and various branches of function theory.

1075. Renfrey Potts (1925-2005)
• In addition to research on Ising-type models in mathematical physics and on road traffic analysis, Potts contributed to three other areas of research: operations research, especially networks; difference equations; and robotics.

1076. George Mackey (1916-2006)
• The new material in the present book is concentrated in the last 50 pages and it centres around lattice models in statistical mechanics, PDEs in hydrodynamics, Kac-Moody Lie algebras, and the Korteweg-de Vries equation.

1077. Antonio Mario Lorgna (1735-1796)
• We indicate below the titles of some of his works but let us record here that, among the pure mathematical topics he worked on, was geometry, convergence of series and algebraic equations.

1078. Aida Yasuaki (1747-1817)
• Aida explained the use of algebraic expressions and the construction of equations.

1079. Pia Nalli (1886-1964)
• In the year 1919 Nalli started to work on issues related to the theory of linear integral equations and the study of integral operators.

1080. Herbert Seifert (1907-1996)
• Seifert, still able to do mathematical research, worked on differential equations and wrote a series of papers on the topic through the war years.

1081. Félix Pollaczek (1892-1981)
• In my theory the task of carrying out these integrations is reduced to the problem of resolving one or several systems of s linear non-homogeneous integro-functional equations of a new kind.

1082. Paul Stäckel (1862-1919)
• In 1891, Stackel's habilitation thesis, Integration of Hamiltonian-Jacobian differential equations by means of separation of variables, was accepted by the University of Halle, near Leipzig, and he took up a lectureship there.

1083. Evgeny Evgenievich Slutsky (1880-1948)
• While at the Kiev Institute of Commerce, Slutsky gave the fundamental equation of value theory to economics.

1084. Roberto Marcolongo (1862-1943)
• In 1906 Marcolongo demonstrated the existence of scalar and vector potentials and defined Lorentz's transformation as the one that left Maxwell's equations unaltered, and in 1913 he studied the transformation laws of various quantities occurring in special relativity.

1085. Fabio Conforto (1909-1954)
• a compilation of formulas and tables of coefficients relevant to a generalisation of the Clapeyron three-moment equation to the case of a continuous beam with piecewise linear variation of bending stiffness, supported at a finite number of points and subject to a uniform transverse loading and to an axial thrust.

1086. Norbert Wiener (1894-1964)
• In 1914 he went to Gottingen to study differential equations under Hilbert, and also attended a group theory course by Edmund Landau.

1087. Egbert van Kampen (1908-1942)
• Wintner had worked at Johns Hopkins since 1930, the year before van Kampen arrived, and his interests were in almost-periodic functions and differential equations.

1088. Joseph Burchnall (1892-1975)
• In both the joint papers and his single author papers he wrote on differential equations, hypergeometric functions and Bessel functions.

1089. Mikhail Krawtchouk (1892-1942)
• He wrote papers on differential and integral equations, studying both their theory and applications.

1090. Gerd Faltings (1954-)
• My main interests are arithmetic geometry (diophantine equations, Shimura-varieties), p-adic cohomology (relation crystalline to etale, p-adic Hodge theory), and vector bundles on curves (Verlinde-formula, loop-groups, theta-divisors).

1091. Thomas Graham (1905-1974)
• Although Graham was as capable and willing as any member of staff to lecture on subjects such as differential equations, he used his influence to ensure that algebra was given its proper place in the curriculum, and it was due to his efforts that the distinguished German algebraist, Hans Zassenhaus spent the year 1948-49 in Glasgow and became his close friend.

• Adrain's first papers in the Mathematical Correspondent concerned the steering of a ship and Diophantine algebra (the study of rational solutions to polynomial equations).

1093. Robert Geary (1896-1983)
• At the Sorbonne, Geary attended lectures by Emile Borel, who held the chair of Theory of Functions, Elie Cartan, who held the Chair of Differential and Integral Calculus, Edouard Goursat, an expert on differential equations, and Henri Lebesgue who was Professor of the Application of Geometry to Analysis.

1094. Guido Grandi (1671-1742)
• Grandi also applied the term "clelies" to the curves determined by certain trigonometric equations involving the sine function .

1095. Benedetto Castelli (1578-1643)
• He remarks with wry amusement on the gay times had by the many knights and gentlefolk in the cardinal's entourage, while he devoted himself instead to the solution of hundreds of equations.

1096. John Raymond Wilton (1884-1944)
• Papers Wilton published during this period include: On plane waves of sound (1913); On the highest wave in deep water (1913); On deep water waves (1914); Figures of equilibrium of rotating fluid under the restriction that the figure is to be a surface of revolution (1914); On the potential and force function of an electrified spherical bowl (1914-15); On ripples (1915); On the solution of certain problems of two-dimensional physics (1915); A pseudo-sphere whose equation is expressible in terms of elliptic functions (1915); and A formula in zonal harmonics (1916-17).

1097. Ernst Hellinger (1883-1950)
• With Toeplitz he wrote a monumental survey of the literature on integral equations up to 1923 for Klein's Enzyklopadie der Mathematischen Wissenschaften.

• He did not neglect his mathematics however, and in 1893 he lectured on differential equations at Tulane University in New Orleans.

1099. Egor Ivanovich Zolotarev (1847-1878)
• He then continued his studies at the Faculty of Physics and Mathematics investigating an indeterminate equation of degree three.

1100. George Chrystal (1851-1911)
• Chrystal's mathematical publications cover many topics including non-euclidean geometry, line geometry, determinants, conics, optics, differential equations, and partitions of numbers.

• Putting chance to work (1989), (with D N Shanbhag) Choquet-Deny type functional equations with applications to stochastic models (1994), (with H Toutenburg) Linear models.

1102. Abram Naumovich Trakhtman (1944-)
• At Bar-Ilan University, Trahtman taught courses in discrete mathematics, theory of sets, algebra, analytical geometry, mathematical logic, finite automata, formal languages, rings and modules, and differential equations.

1103. Archimedes (287 BC-212 BC)
• History Topics: Pell's equation .

• Among other important work which Segre produced was an extension of ideas of Darboux on surfaces defined by certain differential equations.

1105. Johann Castillon (1704-1791)
• He also studied conic sections, cubic equations and artillery problems.
• Among his later mathematical publications we note: Memoire sur la regle de Cardan, et sur les equations cubique, avec quelques remarques sur les equations en general Ⓣ (1783) and two memoirs in 1790 and 1791 entitled Examen philosophique de quelque principes de l'algebre Ⓣ.

1106. Heinrich Bruns (1848-1919)
• He worked on the three-body problem showing that the series solutions of the Lagrange equations can change between convergent to divergent for small perturbations of the constants on which the coefficients of the time depend.

1107. Vitaly Vitalievich Fedorchuk (1942-2012)
• It starts leisurely with the notion of topological metric spaces and their hyperspaces consisting of closed subsets (with the Hausdorff distance or Vietoris topology), but then gathers momentum as it runs through function spaces (metric of uniform convergence, compact-open topology, linear spaces, norm), exponential functors (including parts on connectedness and symmetric products), multivalued mappings (with semicontinuities, selections, retractions), probability measures, spaces of partial mappings, axiomatization of solution spaces for an ordinary differential equation (with a digression on optimal control), and autonomous spaces.

1108. Joel E Hendricks (1818-1893)
• The first few papers in the first part were: On the Relative Positions of the Asteroidal Orbits; The Recurrence of Eclipses; Operations on Imaginary Quantities Considered Geometrically; and Equations of Differences.

1109. Elbert Cox (1895-1969)
• In 1925 Cox was awarded his doctorate for his thesis Polynomial solutions of difference equations.

1110. Philip Kelland (1808-1879)
• He wrote analytical papers on General Differentiation (1839), and Differential Equations (1853), and gave a geometrical Theory of Parallels outlining a version of non-Euclidean geometry.

1111. Marino Ghetaldi (1568-1626)
• We now think of Descartes as founding the application of algebra to geometry, and although Ghetaldi never quite managed to achieve this breakthrough (nowhere in his work are there algebraic equations for geometric objects) nevertheless he came very close.

1112. Felix Bernstein (1878-1956)
• His range of interests were remarkable and he worked on convex functions, isoperimetric problems, the Laplace transform, number theory (including Fermat's Last Theorem), differential equations and the mathematical theory of genetics.

1113. Sergei Fomin (1917-1975)
• He worked with a number of collaborators from 1973 on the writing of a monograph on measure theory and differential equations.

1114. Marston Morse (1892-1977)
• Morse theory is important in the field of global analysis which is the study of ordinary and partial differential equations from a global or topological point of view.

1115. Uriel Rothblum (1947-2012)
• You could do and did many things very well, but nobody, like nobody, could push nasty equations around like you could ..

1116. Hermann von Helmholtz (1821-1894)
• Helmholtz attempted to give a mechanical foundation to thermodynamics, and he also tried to derive Maxwell's electromagnetic field equations from the least action principle.

1117. Edward Maitland Wright (1906-2005)
• He [was] interested in many different strands of analysis, being one of the first to work on difference-differential equations.

1118. Hans Hamburger (1889-1956)
• The work of the first period contains important contributions in two fields; that of differential geometry and partial differential equations, as well as that of continued fractions and the Stieltjes moment problem with which his name is probably most frequently associated.

1119. Zyoiti Suetuna (1898-1970)
• In particular he read Hardy and Littlewood's paper The approximate functional equation in the theory of the zeta function with applications to the divisor problems of Dirichlet and Piltz which appeared in the Proceedings of the London Mathematical Society.

1120. Frank Jackson (1870-1960)
• Over the following couple of years he published two further papers in the same Proceedings, namely A certain linear differential equation (1896) and Certain expansions of xn in hypergeometric series (1897).

1121. Walter Rudin (1921-2010)
• The first is that the choice of topics serves as a superior introduction into much of what is current in analysis, in particular to the branches of harmonic analysis, partial differential equations, several complex variables, and Banach algebras.

• The authors describe the applications to the interpolation by entire functions, to entire and meromorphic solutions of ordinary differential equations, to the Riemann boundary problem with an infinite index and to the arithmetic of the convolution semigroup of probability distributions.

1123. Leopold Löwenheim (1878-1957)
• Lowenheim analysed and improved upon the customary methods of solving equations in the calculus of classes or domains (that is, set theory in its Peirce-Schroder [Charles Peirce and Ernst Schroder] setting) and proved what is now known as Lowenheim's general development theorem for functions of functions.

1124. Enrico Bompiani (1889-1975)
• In 1923-24 Bompiani taught Riemannian geometry and absolute differential calculus at Bologna and, in the following year, first order differential equations.

1125. James Ivory (1765-1842)
• Ivory wrote several articles for encyclopaedias, including the influential Equations in Encyclopaedia Britannica.

1126. Saunders Mac Lane (1909-2005)
• It was elementary differential equations and I learned to understand more about them.

1127. Aleksandr Yakovlevich Khinchin (1894-1959)
• It was first published in 1943 and the eight lectures it contains are: Continuum; Limits; Functions; Series; Derivative; Integral; Series expansions of functions; and Differential equations.

1128. Nikolai Egorovich Zhukovskii (1847-1921)
• Today it is known as the Kutta-Joukowski theorem, since Kutta pointed out that the equation also appears in his 1902 dissertation.

1129. Kristen Nygaard (1926-2002)
• In 1952 he published On the solution of integral equations by Monte-Carlo methods as a Norwegian Defence Research Establishment Report.

1130. John Collins (1624-1683)
• James Gregory's manuscripts on algebraic solutions of equations .

1131. Robert P Langlands (1936-)
• my only active encounter with partial differential equations, a subject to which I had always hoped to return but in a different vein.

1132. George Atwood (1745-1807)
• Atwood also published on equations for the use of Hadley's quadrant.

1133. Béla Gyires (1909-2001)
• In Darstellung symmetrischer regularer Matrizen als Produkt von zueinander transponierten Matrizen Ⓣ he studied the general solution of the matrix equation XX' = F, where F is a real symmetric positive definite matrix.

1134. John Henry Michell (1863-1940)
• The task of determining the velocity potential is then a boundary-value problem for Laplace's equation ..

1135. Jan Tinbergen (1903-1994)
• In his contribution to the debate Tinbergen projected a 'quantitative stylising of the Dutch economy' to isolate the important factors and their effects by means of a set of definitions and equations.

1136. Ernst Stueckelberg (1905-1984)
• Occasionally all three of us would gather around the table while Kramers wrote out a few equations, illustrating how they fitted together to explain some atomic property or other.

1137. Serge Lang (1927-2005)
• Your famous theorem in Diophantine equations earned you the distinguished Cole Prize of the American Mathematical Society.

1138. Wolfgang Krull (1899-1971)
• his earlier studies, but also dealt with other fields of mathematics: group theory, calculus of variations, differential equations, Hilbert spaces.

1139. Helmut Wielandt (1910-2001)
• It was a matter of estimating eigenvalues of non-self-adjoint differential equations and matrices.

1140. Albert Châtelet (1883-1960)
• Clairin, who applied group theory to the solution of differential equations, had published Cours de mathematiques generales Ⓣ (1910).

1141. Henry Scheffé (1907-1977)
• He submitted his doctoral thesis The Asymptotic Solutions of Certain Linear Differential Equations in which the Coefficient of the Parameter May Have a Zero to Wisconsin-Madison and was awarded his PhD in 1935.

1142. Ismail Mohamed (1930-2013)
• from Witwatersrand for his thesis On certain generalisations of equations in groups and the number of solutions while in 1960 he completed his Ph.D.

1143. Gottfried Köthe (1905-1989)
• In the following years I had the pleasure to attend his inspiring lectures on "Hilbert Space Theory", "Partial Differential Equations", "Game Theory" and especially about the field of his main interest "Topological Vector Spaces".

1144. Nicolaus(II) Bernoulli (1695-1726)
• Nicolaus worked on curves, differential equations and probability.

1145. Wilhelm Wirtinger (1865-1945)
• There he attended Felix Klein's lectures on Abelian functions and partial differential equations of physics.

1146. Olli Lehto (1925-)
• Originally not much more than a curiosity, its notions began to pervade the theory of elliptic differential equations in two variables (Lavrent'ev, Morrey), and Teichmuller saw it not merely as an efficient tool in geometric function theory, but as a gateway to new problems of unmistakably classical flavour.

1147. Pierre Cartier (1932-)
• Poisson processes, solutions of stochastic differential equations and an introduction to quantum field theory ..

1148. Ferdinand Rudio (1856-1929)
• He reduced this problem to the problem of solving a differential equation.

1149. Paul Bachmann (1837-1920)
• The book gives in very convenient form the chief results of 284 years of struggle with the problem of proving the possibility or impossibility in integers of the equation xn + yn = zn for values of n greater than 2.

1150. Brian Griffiths (1927-2008)
• We give the titles of a few of his mathematical education article which give an overview of his interests in that topic: Pure mathematicians as teachers of applied mathematicians (1968); Mathematics Education today (1975); Successes and failures of mathematical curricula in the past two decades (1980); Simplification and complexity in mathematics education (1983); The implicit function theorem: technique versus understanding (1984); A critical analysis of university examinations in mathematics (1984); Cubic equations, or where did the examination question come from? (1994); The British Experience of Teaching Geometry since 1900 (1998); and The Divine Proportion, matrices and Fibonacci numbers (2008).

1151. Samuel Karlin (1924-2007)
• These ideas play a basic role in problems involving convexity, moment spaces, orthogonal polynomials, Chebyshev systems, the oscillation properties of linear differential equations, and the theory of approximation.

1152. Arthur Eddington (1882-1944)
• It was Dirac's 1928 paper on the wave equation of the electron which had first set Eddington on the path of seeking ways to unify quantum mechanics and general relativity.

1153. Jacques Binet (1786-1856)
• Suppose a and b are the roots of the equation x2 - x - 1 = 0 where a - b = √5.

• The school provided a solid background in mathematics, including topics in the foundations of analysis, differential equations and complex variables.

1155. Louis Carré (1663-1711)
• Between 1701 and 1705, Carre published over a dozen papers on a variety of mathematical and physical subjects: Methode pour la rectification des lignes courbes par les tangentes Ⓣ (1701); Solution du probleme propose aux Geometres dans les memoires de Trevoux, des mois de Septembre et d'Octobre Ⓣ (1701); Reflexions ajoutees par M Carre a la Table des Equations Ⓣ (1701); Observation sur la cause de la refraction de la lumiere Ⓣ (1702); Pourquoi les marees vont toujours en augmentant depuis Brest jusqu'a Saint-Malo, et en diminuant le long des cotes de Normandie Ⓣ (1702); Nombre et noms des instruments de musique Ⓣ (1702); Observations sur la vinaigre qui fait rouler de petites pierres sur un plan incline Ⓣ (1703); Observation sur la rectification des caustiques par reflexions formees par le cercle, la cycloide ordinaire, et la parabole, et de leurs developpees, avec la mesure des espaces qu'elle renferment Ⓣ (1703); Methode pour la rectification des courbes Ⓣ (1704); Observation sur ce qui produit le son Ⓣ (1704); Examen d'une courbe formee par le moyen du cercle Ⓣ (1705); Experiences physiques sur la refraction des balles de mousquet dans l'eau, et sur la resistance de ce fluide Ⓣ (1705); and Probleme d'hydrodynamique sur la proportion des tuyaux pour avoir une quantite d'eau determinee Ⓣ.

1156. Ernest Esclangon (1876-1954)
• Esclangon elaborated a theory for these functions, studied their differentiation and integration, and examined the differential equations which allow them as coefficients.
• His important mathematics paper, Sur les integrales bornees d'une equation differentielle lineaire Ⓣ, was published in Comptes rendus in 1915.

1157. Carl Størmer (1874-1957)
• Poincare had, in the same year, solved the differential equations resulting from the motion of a charged particle in the field of a single pole.

1158. Hans Wussing (1927-2011)
• His main thesis, ably defended and well documented, is that the roots of the abstract notion of group do not lie, as frequently assumed, only in the theory of algebraic equations, but that they are also to be found in the geometry and the theory of numbers of the end of the 18th and the first half of the 19th centuries.

1159. Émile Borel (1871-1956)
• In [',' M Frechet, La vie et l’oeuvre d’Emile Borel, Enseignement mathematique 11 (1965), 1-95.','8] Borel's mathematical work is divided into the following topics: Arithmetic; Numerical series; Set theory; Measure of sets; Rarefaction of a set of measure zero; Real functions of real variables; Complex functions of complex variables; Differential equations; Geometry; Calculus of probabilities; and Mathematical physics.

1160. Garrett Birkhoff (1911-1996)
• He attended a course on potential theory given by Oliver Kellogg which gave him a good understanding of differential equations.

1161. Richard Feynman (1918-1988)
• Feynman seemed to possess a frightening ease with the substance behind the equations, like Einstein at the same age, like the Soviet physicist Lev Landau - but few others.

1162. Charles Merrifield (1827-1884)
• This was on the strength of some excellent mathematical papers on the calculation of elliptic functions, the first of which was The geometry of the elliptic equation which he published in 1858.

1163. Hermann Weyl (1885-1955)
• This thesis investigated singular integral equations, looking in depth at Fourier integral theorems.

1164. Gian-Carlo Rota (1932-1999)
• The topics were wide-ranging: differential equations, ergodic theory, nonstandard analysis, probability, and of course, combinatorics.

1165. Beno Eckmann (1917-2008)
• Peter Hilton, who had been a personal friend of Eckmann's for many years spoke in detail of Eckmann's research in topology: continuous solutions of systems of linear equations, a group-theoretical proof of the Hurwitz-Radon theorem, complexes with operators, spaces with means, simple homotopy type.

1166. J W S Cassels (1922-2015)
• After further papers on Diophantine equations and Diophantine approximation he wrote a series of five papers on Some metrical theorems in Diophantine approximation.

1167. Nicolaas de Bruijn (1918-2012)
• He began publishing papers on combinatorics relevant to his work during this period such as The problem of optimum antenna current distribution (1946), A combinatorial problem (1946), On the zeros of a polynomial and of its derivative (1946), and A note on van der Pol's equation (1946) [',' F D Kamareddine, Editorial preface, in F D Kamareddine (ed.), Thirty-five years of automating mathematics, Applied Logic Series 28 (Kluwer Academic Publishers, Dordrecht, 2003).','1]:- .

1168. Douglas Jones (1922-2013)
• Together with Brian Sleeman, Jones published the textbook Differential equations and mathematical biology in 1983.

1169. Donald Eperson (1904-2001)
• He was the author of The differential calculus (1935) and (with Bryce McLeod) Elementary differential equations (1969).

1170. Horace Lamb (1849-1934)
• In a famous paper in the Proceedings of the London Mathematical Society he showed how Rayleigh's results on the vibrations of thin plates fitted with the general equations of the theory.

1171. Wolfgang Gaschütz (1920-2016)
• This is an example that shows how minor variations of the initial conditions can influence the solutions of an equation considerably.

1172. Hans Hahn (1879-1934)
• These include a report on integral equationS he wrote in 1911, his modification of Hellinger's theory of invariants of quadratic forms, in which he dispensed with the use of the Hellinger integral, and his work on duality in Banach spaces, culminating with his proof of the Hahn-Banach theorem in 1927.

1173. Oded Schramm (1961-2008)
• Schramm was recognized for his development of stochastic Loewner equations and for his contributions to the geometry of Brownian curves in the plane.

1174. Edmond Bour (1832-1866)
• Bour continued his studies at the Ecole des Mines in Paris and worked on a major paper Sur l'integration des equations differentielles de la mecanique analytique Ⓣ which was read before the Academie des Sciences on 5 March 1855 and published in the Journal de mathematiques pures et appliquees.
• in line with the analogous studies of Bonnet and Codazzi, contained several theorems on ruled surfaces and minimal surfaces; but in its printed version this work does not include the test for the integration of the problem's equations in the case of surfaces of revolution, which had enabled Bour to surpass the other competitors for the Academy's grand prize.

1175. Herbert Turnbull (1885-1961)
• Turnbull's major beautifully written works include The Theory of Determinants, Matrices, and Invariants (1928), The Great Mathematicians (1929), Theory of Equations (1939), The Mathematical Discoveries of Newton (1945), and An Introduction to the Theory of Canonical Matrices (1945), which was jointly written with Aitken.

1176. Carl Neumann (1832-1925)
• In 1890 Emile Picard used Neumann's results to develop his method of successive approximation which he used to give existence proofs for the solutions of partial differential equation.

1177. Alexander Burgess (1872-1932)
• And Concurrency of lines joining vertices of a triangle to opposite vertices of triangles on its sides; determinants connected with the periodic solutions of Mathieu's equation.

1178. Sof'ja Aleksandrovna Janovskaja (1896-1966)
• An analysis is given for the problem of finding geometric solutions for algebraic equations of degree higher than two by locating points of intersection of conic sections with other curves.

1179. Naum Il'ich Akhiezer (1901-1980)
• Examples of his papers from his time in Kiev are: On polynomials deviating least from zero (Russian) (1930), On the extremal properties of certain fractional functions (Russian) (1930), On a minimum problem in the theory of functions, and on the number of roots of an algebraic equation which lie inside the unit circle (Russian) (1931), and Uber einige Funktionen, welche in zwei gegebenen Intervallen am wenigsten von Null abweichen Ⓣ (3 parts, 1932-1933).

1180. René de Sluze (1622-1685)
• This work was on geometrical construction in which he discussed the cubature of various solids and the solutions to third and fourth degree equations which he obtained geometrically using the intersection of any conic section with a circle.

1181. Thomas Stieltjes (1856-1894)
• Stieltjes also contributed to ordinary and partial differential equations, the gamma function, interpolation, and elliptic functions.

1182. William Berwick (1888-1944)
• Berwick also gave, in 1915, necessary and sufficient conditions for a quintic equation to be soluble by radicals.

1183. Alexis Bouvard (1767-1843)
• Using all the data at his disposal, Bouvard produced a system of 77 equations but was unable to find a possible orbit for the planet from them.

1184. Marceli Stark (1908-1974)
• In 1948 he published On a functional equation and, in the following year, the paper On a ratio test of Frink in which he gives an extension of Raabe's test for convergence.

1185. Georg Pick (1859-1942)
• However more than half of his papers were on functions of a complex variable, differential equations, and differential geometry.

1186. Nicolae Abramescu (1884-1947)
• There he was a fellow student of Traian Lalescu (1882-1929) who also went on to become an important mathematician working mainly on integral equations.

1187. Victor Olunloyo (1935-)
• Vincent Olunloyo spent time at Cornell University in the United States and wrote papers on ordinary and partial differential equations, fluid mechanics and numerical analysis.

1188. Nicolas Vilant (1737-1807)
• Those parts for which some originality may be claimed are: (a) a method for finding the cube root of binomials of form R ± √S, where S may be positive or negative, and (b) a method for finding rational and whole-number solutions of indeterminate problems involving linear, quadratic and cubic equations.

1189. Eugène Catalan (1814-1894)
• In the same journal, he published two papers in 1838: Note sur un Probleme de combinaisons Ⓣ, and Note sur une Equation aux differences finies Ⓣ.
• Four papers by Catalan are published in Volume 4 in 1839: Note sur la Theorie des Nombres Ⓣ; Solution nouvelle de cette question: Un polygone etant donne, de combien de manieres peut-on le partager en triangles au moyen de diagonales? Ⓣ; Addition a la Note sur une Equation aux differences finies Ⓣ; and Memoire sur la reduction d'une classe d'integrales multiples Ⓣ.
• Two consecutive whole numbers, other than 8 and 9, cannot be consecutive powers; otherwise said, the equation xm - yn = 1 in which the unknowns are positive integers only admits a single solution.

1190. Leopold Pars (1896-1985)
• He based his treatment on the theorem of Lagrange that he called the fundamental equation, which he proceeded to translate into six different forms, each exploited in appropriate contexts.

1191. Frigyes Riesz (1880-1956)
• He built on ideas introduced by Frechet in his dissertation, using Frechet's ideas of distance to provide a link between Lebesgue's work on real functions and the area of integral equations developed by Hilbert and his student Schmidt.

1192. George Dantzig (1914-2005)
• It was a system with nine equations in seventy-seven unknowns.

1193. Erasmus Bartholin (1625-1698)
• The problem is the first example of an inverse tangent problem which in modern notation results in requiring the solution to the differential equation .

1194. William Ferrel (1817-1891)
• However this assumption is not realistic, but the realistic assumption that the friction is proportional to the square of the velocity produced non-linear equations which were much more difficult to treat.

1195. Bronius Grigelionis (1935-2014)
• A wide class of one-dimensional strictly stationary diffusions with the Student's t-marginal distribution is defined as the unique weak solution for the stochastic differential equation.

1196. Nathan Mendelsohn (1917-2006)
• He wrote papers on a wide variety of combinatorial problems, for example: Symbolic solution of card matching problems (1946), Applications of combinatorial formulae to generalizations of Wilson's theorem (1949), Representations of positive real numbers by infinite sequences of integers (1952), A problem in combinatorial analysis (1953), The asymptotic series for a certain class of permutation problems (1956), and Some elementary properties of ill conditioned matrices and linear equations (1956).

1197. David Rees (1918-2013)
• [He] was never happier than when sitting in front of the television scribbling down algebraic equations to find a solution to some mathematical challenge he had set himself.

1198. Paul Halmos (1916-2006)
• its purpose was to reveal the secrets of quadratic equations (for which there was a formula) and parentheses (which were abominable entities and had to be eliminated at the drop of a hat).

1199. Kathleen Ollerenshaw (1912-2014)
• Before falling asleep, I 'drew' with my finger any relevant geometrical figure or algebraic equation on the partitioning of the dormitory cubicle that formed a bedside wall.

1200. Hans Blichfeldt (1873-1945)
• Some of the many topics that he covered were diophantine approximations, orders of linear homogeneous groups, theory of geometry of numbers, approximate solutions of the integers of a set of linear equations, low-velocity fire angle, finite collineation groups, and characteristic roots.

1201. Eugène Cosserat (1866-1931)
• The most practical results concerning elasticity were the introduction of the systematic use of the movable trihedral and the proposal and resolution, before Fredholm's studies, of the functional equations of the sphere and ellipsoid.

1202. Teiji Takagi (1875-1960)
• Hilbert had left this topic immediately after writing the Zahlbericht and by the time Takagi reached Gottingen he was engaged in studying the foundations of geometry and then integral equations.

1203. Louise Szmir Hay (1935-1989)
• Until high school, I was not particularly mathematically inclined - indeed, I was much better at verbal subjects; combinatorial aspects of numbers and equations have never been my strong point ..

1204. Al-Biruni (973-1048)
• These include: theoretical and practical arithmetic, summation of series, combinatorial analysis, the rule of three, irrational numbers, ratio theory, algebraic definitions, method of solving algebraic equations, geometry, Archimedes' theorems, trisection of the angle and other problems which cannot be solved with ruler and compass alone, conic sections, stereometry, stereographic projection, trigonometry, the sine theorem in the plane, and solving spherical triangles.

1205. Jacques Français (1775-1833)
• It was a work on the integration of first order partial differential equations, but the memoir had been lost so there are few details as to its precise contents.

1206. Thomas Bayes (1702-1761)
• This notebook contains a considerable amount of mathematical work, including discussions of probability, trigonometry, geometry, solution of equations, series, and differential calculus.

1207. William Birnbaum (1903-2000)
• After arriving in Gottingen, Edmund Landau became his advisor, and he attended several lecture courses: differential equations given by Courant; calculus of variations given by Courant; power series given by Landau; higher geometry given by Herglotz; probability calculus given by Bernays; analysis of infinitely many variables given by Wegner; and attended the mathematical seminar directed by Courant and Herglotz.

1208. Chris Zeeman (1925-2016)
• I suppose I am particularly fond of having unknotted spheres in 5-dimensions, of spinning lovely examples of knots in 4-dimensions, of proving Poincare's Conjecture in 5-dimensions, of showing that special relativity can be based solely on the notion of causality, and of classifying dynamical systems by using the Focke-Plank equation.

1209. Nathan Divinsky (1925-2012)
• You use a lot of differential equations and what is called the maximum likelihood function.

1210. Eduard Kummer (1810-1893)
• He extended Gauss's work on hypergeometric series, giving developments that are useful in the theory of differential equations.

1211. Philipp Furtwängler (1869-1940)
• He lectured without notes and had an assistant who wrote equations on the blackboard.

1212. August Yulevich Davidov (1823-1885)
• As well as his work on the equilibrium of a floating body, Davidov also worked on partial differential equations, elliptic functions and the application of probability to statistics.

1213. Naum Il'ich Feldman (1918-1994)
• The last part of the book describes Alan Baker's work on linear forms in the logarithms of algebraic numbers and its applications to Diophantine equations and to the determination of imaginary quadratic fields with class number 1 or 2.

1214. Alfred Foster (1904-1994)
• Equational characterization of factorization in Mathematische Annalen.

1215. Wilhelm Blaschke (1885-1962)
• In Leipzig he became a close friend of Gustav Herglotz who was interested in partial differential equations, function theory and differential geometry, and succeeded Runge in Gottingen 10 years later.

## History Topics

1. Weather forecasting
• 3.3 Primitive Equations .
• Moreover, the primitive equations describing atmospheric processes, which are used in forecasting models, are presented and explained as well.
• The finite element method, which is another method for numerically solving partial differential equations, is described briefly.
• Furthermore, I have assumed that the reader is familiar with differential equations, differentiation of functions of several variables, Fourier series and Gaussian elimination.
• However, as the article should provide only an overview of the mathematical methods used in current forecasting models, I have chosen to include only simple equations and explain some mathematical symbols in order to make understanding the methods easier.
• Also, a number of mathematical concepts are explained in words rather than with equations.
• In the early 20th century, scientists, in particular Vilhelm Bjerknes and Lewis Fry Richardson, pioneered numerical weather forecasting, which is based on applying physical laws to the atmosphere and solving mathematical equations associated to these laws.
• We must apply the equations of theoretical physics not to ideal cases only, but to the actual existing atmospheric conditions as they are revealed by modern observations.
• Bjerknes' equations were very complicated and not very practical for predicting the weather as they required immense computational power, a fact of which he was aware himself.
• Nevertheless, he firmly believed that one day, meteorology would be a proper science and weather forecasts based on solving mathematical equations would be feasible: .
• The first attempt to use mathematics in order to predict the weather was made by the British mathematician Lewis Fry Richardson (1881-1953), who simplified Bjerknes' equations so that solving them became more feasible.
• He also worked for the National Peat Industries for some time, and in order to solve differential equations modelling the flow of water in peat, he invented his method for finite differences, which produces highly accurate results.
• Basically, this method allows finding approximate solutions to differential equations.
• A differential equation with a smooth variable is converted into a function (or an approximation thereof) that relates the changes of the variable and given steps in time and/or space, meaning that the changes are calculated at discrete points rather than at infinitely many points.
• Then the derivatives in the differential equation are replaced by finite difference approximations (this method will be explained in more detail in section 4.1).
• So in the place of the differential equation you get many equations which can be solved using arithmetic.
• He remodelled the fundamental equations describing atmospheric processes such that it was possible to solve them numerically.
• By dividing the surface of the Earth into thousands of grid squares, and the atmosphere into several horizontal layers, he obtained a large number of grid boxes, connected to one another by mathematical equations.
• In terms of numerical weather prediction, this equation is important as it facilitated extended five-day forecasts [','J D Cox, Stormwatchers.
• The prerequisite for computer-generated forecasts was to simplify the full primitive equations that govern the atmosphere (they will be discussed in section 3.3), as the early computers were unable to deal with all the equations included in Richardson's model.
• In 1948, Charney developed the quasi-geostrophic approximation, which reduces several equations of atmospheric motions to only two equations in two unknown variables [','R S Harwood, Atmospheric Dynamics (Chapter 1: Basics, Chapter 5: Balance of Forces in Synoptic Scale Flow, Chapter 13: Quasi-Geostrophic Equations) (University of Edinburgh, 2005) ','14, chapter 13].
• These equations are much easier to solve and could be handled by the early computers.
• Furthermore, this approximation filters out all but the slow long-wave motions that are important in meteorology, so that you do not have to solve the primitive equations for acoustic and gravity waves as Richardson did 30 years earlier.
• Although the computers were fed with simplified equations only, the limited computer power demanded a barotropic (i.e.
• In 1963, a six-layer model based on the primitive equations was used for producing a forecast.
• Since then, as computer power increased, the models have constantly been refined (meaning that more layers, a finer grid, more equations, topography and landscape characteristics were included) [','R B Stull, Meteorology for Scientists and Engineers, second edition (Pacific Grove CA, 2000)','4, p.
• Lorenz reasoned that the dynamical equations that describe the atmosphere are exceedingly sensitive to initial conditions.
• Dynamical equations are deterministic; meaning that given initial conditions, they determine how the process they describe will evolve in the future.
• But before looking at current forecasting models, let us look at the primitive equations that form the basis of every such model.
• 3.3) nnnnnPrimitive Equations .
Go directly to this paragraph
• Scientists treat the Earth's atmosphere as if it were a fluid on a rotating sphere in order to describe large-scale atmospheric processes using the fundamental laws of thermodynamics and hydrodynamics, also called the primitive equations.
• Essentially, they are the equations of motion, one for each of the three wind directions, the continuity equation, describing the conservation of mass, the ideal gas law, and the first law of thermodynamics, describing the conservation of energy.
• There is also an equation for determining the humidity, which is not always included in the set of the primitive equations (and is not treated here).
• Here, only the very basic versions of the primitive equations are described.
• The equations of motion are based on Newton's second law : force equals the product of mass and acceleration.
• Thus, the equation of motion can be rewritten as .
• Then the equations of motion in spherical coordinates are: .
• The basic principle underlying the continuity equation is the conservation of mass.
• The continuity equation is used to determine the air density.
• In the Eulerian reference frame, the continuity equation is .
• Substituting the continuity equation by the above filter condition is called anelastic approximation [','G Doms, U Schattler, A Description of the Nonhydrostatic Regional Model LM.
• The pressure in an air parcel is found using the equation of state, which relates pressure, temperature and density.
• The equation describing the change of temperature T with respect to time t is: .
• The other processes in the equation are adiabatic, meaning that there is no heat transfer.
• The primitive equations were first used in a weather forecast by Lewis Fry Richardson.
• Jule Charney and his colleagues had simplified them so that the early computers could handle them, but nowadays meteorologists have gone back to use all of Richardson's equations.
• All current weather forecasting models are based on the primitive equations -- or versions thereof -- but each model uses different approximations and assumptions, resulting in slightly different outcomes.
• Also, the models include equations accounting for the effects of small-scale processes such as convection, radiation, turbulence and the effects of mountains that cannot be represented explicitly by the forecasting models, as their resolution is not high enough.
• Some models, such as the regional model COSMO developed by the German weather service Deutscher Wetterdienst (DWD), have therefore abandoned this assumption and are based on non-hydrostatic thermodynamic equations (similar to the equations used in fluid mechanics).
• smaller grid spacing), but as a result, the primitive equations are much more complex and computationally more demanding as vertical wind components are included in the model [','http://www.dwd.de','29].
• Again, the primitive equations have to be re-written in terms of ζ [','G Doms, U Schattler, A Description of the Nonhydrostatic Regional Model LM.
• But let us now look at the methods employed by meteorologists to solve these equations.
• Similarly, Richardson's finite difference method is not the only method for solving the primitive equations anymore; its strongest "opponent" is the so-called spectral method, which will be described in section 4.2.
• Before the primitive equations can be solved, they have to be discretized with respect to space and time.
• The atmosphere is then divided into a number of layers, resulting in a three-dimensional grid, in which the primitive equations can be solved for each grid point.
• The regional model of the DWD has a resolution of 7 km, and the local model has a resolution of up to 2.8 km (the Met Office's models have coarser resolution as the Met Office does not work with non-hydrostatic equations).
• The great advantage of the triangular grid is that the primitive equations can be solved in air parcels close to the poles without any problems, as opposed to the rectangular grid, where the longitudes approach each other, resulting in erroneous computations.
• Now, the primitive equations have to be re-written in finite difference form.
• The implicit scheme, on the other hand, is absolutely stable, but it results in a system of simultaneous equations, so is more difficult to solve [','R W Riddaway, Numerical Methods, revised March 2001 (by M Hortal) (Meteorological Training Course Lecture Series, 2002) ','17, p.
• When the primitive equations are expressed in terms of finite differences, the equations soon become very long and take some computational effort to solve.
• This means that the primitive equations are subdivided into forcing terms fψ referring to slowly varying modes and source terms sψ directly related to the fast-moving sound waves: .
• representing a set of equations that can be solved using Gaussian elimination [','G Doms, U Schattler, A Description of the Nonhydrostatic Regional Model LM.
• For equations including acoustically active terms, i.e.
• If you re-write the primitive equations using finite differences, you get, "after considerable algebra" [','G Doms, U Schattler, A Description of the Nonhydrostatic Regional Model LM.
• 67], a linear tridiagonal system of simultaneous equations which can be written in the general form .
• The equation system can be solved for using a solving method based on Gaussian elimination and back-substitution.
• In a nutshell, the derivatives in the primitive equations can be approximated by finite differences, such that the equations can be transformed into a linear equation system.
• It takes modern supercomputers at the leading weather services quite a while to solve all these equations, so it is astonishing that Richardson managed to produce a numerical weather forecast at all, even if it was for a limited area.
• However, the application of this method to the primitive equations was crucial to the development of numerical weather forecasting, as it was the only mathematical method that could simplify partial differential equations needed for forecasting for several decades.
• A further disadvantage of the finite difference method, other than the great number of equations you have to solve, is that it does not reveal anything about the behaviour of the variables between the individual grid points.
• One of the advantages of the spectral method is that the primitive equations can be solved in terms of global functions rather than in terms of approximations at specific points as in the finite difference method.
• The partial differential equations are represented in terms of spherical harmonics, which are truncated at a total wave number of 799.
• When this series is substituted into an equation of the form Lψ = f (x), where L is a differential operator, you get a so-called residual function: .
• The residual function is zero when the solution of the equation above is exact, therefore the series coefficients an should be chosen such that the residual function is minimised, i.e.
• A simple example that can be solved in terms of a Fourier series illustrates the idea of the spectral method: One of the processes described by the primitive equations is advection (which is the transport of for instance heat in the atmosphere), and the non-linear advection equation is given by .
• Having chosen appropriate boundary conditions, the equation can be expanded in terms of a finite Fourier series: .
• The advection equation then is: .
• As each of the terms on the left-hand side of the equation has been truncated at a different wave number, there will always be a residual function.
• There are several methods which convert differential equations to discrete problems, for example the least-square method or the Galerkin method, and which can be used in order to choose the time derivative such that the residual function is as close to zero as possible [','R W Riddaway, Numerical Methods, revised March 2001 (by M Hortal) (Meteorological Training Course Lecture Series, 2002) ','17, p.
• It is difficult to calculate the non-linear terms of a differential equation in the context of the spectral method, but you can get around this problem by using a so-called transform method.
• Using a transform method requires three steps, which will be shown for the non-linear term in the advection equation above: .
• Still, using transform methods is necessary in order to solve differential equations in spectral space.
• Spherical harmonics Ynm(λ, φ) are the angular part of the solution to Laplace's equation.
• At the poles, the solutions to differential equations become infinitely differentiable; therefore the poles are usually excluded from the spectral space, which actually simplifies the method [','J P Boyd, Chebyshev and Fourier Spectral Methods, second edition (Mineola NY, 2000) ','5, p.
• A third technique for finding approximate solutions to partial differential equations and hence to the primitive equations is the finite element method.
• The domain for which the partial differential equations have to be solved is divided into a number of subdomains, and a different polynomial is used to approximate the solution for each subdomain.
• These approximations are then incorporated into the primitive equations.
• One of the easiest ways to increase the quality of weather predictions is to increase the orders of the numerical approximations to partial differential equations.

2. African women 1
• Thesis title: Numerical solutions of integral equations.
• She has published at least 15 papers including A numerical method for locating the zeros and poles of a meromorphic function (1970), On the numerical solution of integral equations with singular kernels (1975), A regularization technique for a class of singular integral problems (1976), An asymptotic expansion for a regularization technique for numerical singular integrals and its application to Volterra integral equations (1979), A fast method for the numerical solution of singular integro-differential equations (1986), and A computational approach for optimal control systems governed by parabolic variational inequalities (2003).
• She has published around 20 papers including On p-nuclear and entropy quasinorms in Banach spaces (1979), On projection constant problems and the existence of metric projections in normed spaces (2001), On the projection constants of some topological spaces and some applications (2001), Interpolation methods to estimate eigenvalue distribution of some integral operators (2004), On The General Term of a Cauchy Product of Two Series of The Truncation Error for Some Restrictive Approximations for IBVP for Parabolic and Hyperbolic Equations (2004), Finite co-dimensional Banach spaces and some bounded recovery problems (2004), Generalization of Banach contraction principle in two directions (2007), Two population three-player prisoner's dilemma game (2016), The payoff matrix of repeated asymmetric 2×2 games (2016).
• Her interests are Partial differential equations, Functional Analysis, Mathematical Physics.
• She has published around 35 papers including Evolution Problems involving non-stationary Operators between two Banach Spaces I (1985), Fractional Powers of a Closed Pair of Operators between two Banach Spaces (1986), On the Solvability of the Boundary-value Problem for the Elastic Beam with Attached Load (1994), Interlude of Operators and a Von Karman Plate-beam Problem with Rotational Inertia(2000), Well-posedness of the equations governing the motions of a one-dimensional hybrid thermo-elastic structure (2005), Strong stabilization of a structural acoustic model which incorporates shear and thermal effects in the structural component (2010), Polynomial decay rate of a thermoelastic Mindlin-Timoshenko plate model with Dirichlet boundary conditions (2015).
• She has published Discontinuous finite element basis functions for nonlinear partial differential equations (1989), again under the name Meiring.
• Thesis title: Unicite, non unicite et continuite Holder du probleme de Cauchy pour des equations aux derivees partielles: propagation du front d'onde C*(L) pour des equations non lineaires.
• She published several papers such as On the order of the product set of two basic sets of polynomials (1982/83), On the order of the sum set of two basic sets of polynomials (1984), On the type on a circle of basic sets of polynomials associated with functions of nonalgebraic semi-block matrices (1990), On the successive approximate solutions of the differential equation Y" - (x + ax5)y= 0 (1991), On the order and logarithmic order of entire functions and of basic sets of polynomials in equipolycylinders (1993) and On basic sets of polynomials of two complex variables (1994).
• Thesis title: Numerical solution of hyperbolic partial differential equations.
• These models lead to partial differential equations which can be solved to obtain the credit spreads for risky bonds.
• we consider an interest rate driven by a stochastic differential equation.
• Biographical Data: Here is the Abstract of her thesis: "We seek formulas for obtaining differential equations of the Laguerre-Hahn polynomials: the associated Stieltjes function satisfies a Rccati equation.
• We shows that these polynomials satisfy either a differential equation of the second order, or a differential equation of the fourth order." .
• Thesis title: Accuracy of the multi-step methods for solving differential equations.
• She has published around 30 papers including Capillary instability of a viscous hollow cylinder (1987), Exact solution of time fractional partial differential equation (2008), Hydromagnetic stability of oscillating hollow jet (2011), Axisymmetric hydromagnetic stability of a streaming resistive hollow jet under oblique varying magnetic field (2012), Stability of streaming compressible fluid cylinder pervaded by axial magnetic field and surrounded by different magnetic field (2015).
• Biographical Data: She published Spline-Gauss rules and the Nystrom method for solving integral equations in quantum scattering (1987) which was part of her thesis.
• The spline-Gauss quadrature is used in a Nystrom method for solving integral equations of the second kind.
• A practical application is provided by solving integral equations that arise in quantum scattering theory." At this time she was at the National Research Institute for Mathematical Sciences at the Council for Scientific and Industrial Research, Pretoria.
• Thesis title: A study of pseudospectral Mmethods for the solution of a nonlinear dispersive wave equation.
• The Abstract of the thesis is as follows: "This thesis examines time-stepping techniques for the numerical solution of the Korteweg - de Vries (KDV) equation by pseudospectral spatial discretization.
• The KDV equation is an ubiquitous nonlinear dispersive wave equation.
• To appreciate the numerical difficulties and to understand the need for solutions to such equations it is necessary to know a little about the fascinating array of solutions which arise in the study of dispersive wave equations.
• This analysis is used in a later chapter to seek numerical solutions of the KDV equation.
• The remainder of the thesis concerns a further generalization, allowing the investigation of stability and efficiations for Chebyshev pseudospectral methods and their applications to solve nonlinear dispersive wave equations, namely the KDV equation with general boundary conditions.
• She has published around 50 papers, all published under the name Assia Benabdallah except the first which is under the name Assia Lagha-Benabdallah, including Limites des equations d'un fluide compressible lorsque la compressibilite tend vers zero (1984), Stabilisation de l'equation des ondes par un controleur dynamique (1995), Exponential decay rates for a full von Karman system of dynamic thermoelasticity (2000), Null controllability of a thermoelastic plate (2002), Null-controllability of some reaction-diffusion systems with one control force (2006), Carleman estimates for the one-dimensional heat equation with a discontinuous coefficient and applications to controllability and an inverse problem (2007), Inverse problem for a parabolic system with two components by measurements of one component (2009), Recent results on the controllability of linear coupled parabolic problems: a survey (2011) and New phenomena for the null controllability of parabolic systems: minimal time and geometrical dependence (2016).
• Her published work includes Temperature-dependent viscosity and thermal conductivity in steady flow along a semi-infinite plate (1992), The dependence of the modulus of elasticity on reference temperature in generalized thermoelasticity with thermal relaxation (2004), State space formulation for magnetohydrodynamic free convection flow with two relaxation times (2004), Analytical and numerical methods for the momentum, species concentration and energy equations of a viscous incompressible fluid along a vertical plate (2010) and One-dimensional problem of a conducting viscous fluid with one relaxation time (2011).
• As an example of her work we give the Abstract of the 2011 paper: "We introduce a magnetohydrodynamic model of boundary-layer equations for conducting viscous fluids.
• The method of the matrix exponential formulation for these equations is introduced.
• Thesis title: Contribution a l'etude des equations d'Hamilton-Jacobi.
• She published Equations d'Hamilton-Jacobi du premier ordre avec termes integro-differentiels Parties I et II (1991), Stability results for Hamilton-Jacobi equations with integro-differential terms and discontinuous Hamiltonians (2002), On the observers for a class of discrete bilinear systems (2007) and Kernel density smoothing using probability density functions and orthogonal polynomials (2016).
• After a review of the various models described in the literature, our study deals with the simple zero-equation model and the more complex two-equation model of the k-e kind.
• She has published papers including Oscillations in vector spaces: a comparison result for monotone delay differential systems (1991), Subdominant behavior in positive semigroups: the case of a class of delay differential equations (1996), Oscillations in differential equations with state-dependent delays (2003), Fluctuations in a SIS epidemic model with variable size population (2010), Global Stability of an Epidemiological Model with Relapse and Delay (2014, and Global asymptotic stability of an SIS epidemic model with variable population size and a delay (2017).
• Thesis title: On integrodifferential equations and mathematical models in population dynamics.
• The Abstract of the thesis is as follows: "The main purpose of this dissertation is to improve results for the oscillations of neutral differential equations of odd order.
• New necessary and sufficient conditions for all solutions of an integrodifferential equation to have at least one zero crossing is obtained.
• An application to a Logistic integrodifferential equation is discussed.
• We introduce new results for global asymptotic stability in a competition system of four competitive species modelled by autonomous delay integrodifferential equations are obtained.
• She has published On analyse the behaviour of the solutions on a bounded set (2000), Oscillatory and non-oscillatory behaviour of second-order neutral delay differential equations (2003) and Stability and persistence in plankton models with distributed delays (2003).

3. African men 1
• Thesis title: Les cas essentiellement geodesiques des equations de Hamilton-Jacobi integrables par separation des variables [The essentially geodesic cases of Hamilton-Jacobi equations integrable by the separation of variables] .
• Thesis title: Periodic Solutions of Non-linear Differential Equations of Second Order.
• Thesis title: Some topics in the theory of non-linear differential equations of the third order.
• Thesis title: Iterative Solution of Equations in Linear Topological Spaces.
• Biographical Data: He was awarded an M.Sc (1961) from McGill University, Canada, for the thesis On infinitely many algorithms for the solution of an analytic equation.
• His papers include Total convexity for parametric multiple integrals in the calculus of variations (1970), On continuous descent functions for polynomial equations (1976), Copositive matrices and definiteness of quadratic forms subject to homogeneous linear inequality constraints (1981), On the Walach-Zeheb multivariable positivity test (1983), and A characterisation of semi-Fredholm operators defined on almost reflexive Banach spaces (1986).
• The stability of plane Poiseuille flow of slightly viscoelastic liquids (1965), The explicit form of the differential operator for the Oldroyd rate type constitutive equation (Chinese) (1984), Comments on the solutions of boundary value problems in non-Newtonian fluid mechanics (1996), Advanced mathematics for applied and pure sciences (1997), Perturbation methods, instability, catastrophe and chaos (1999), Advanced mathematics for engineering and science (2003) and Polar fluid flow between two eccentric rotating cylinders: inertial effects (2005).
• His research concerned partial differential equations and biological mathematics.
• Thesis title: Probleme inverse de la diffusion et generalisation de l'equation de Marchenko [Inverse problem of diffusion and generalisation of Marchenko's equation].
• He has published around 10 papers including Controle ponctuel d'un systeme gouverne par une equation parabolique comportant des masses de Dirac (1981), Resolution d'un systeme gouverne par une equation parabolique fortement non lineaire (1988), Sur un probleme de dynamique des populations (2003), and Sentinelles a deux temps et structure des pollutions non detectables par un ensemble de sentinelles (2008).
• He is a chief representative of Nigeria's very strong school in ordinary differential equations.
• His recent interests are towards stability and boundedness of solutions to higher order equations.
• He has published around 50 papers including A multiplier problem for a semigroup algebra of an ordered semigroup (1975), Vector Lyapunov functions and p th-order conditional stability and boundedness (1979), On partial boundedness of differential equations with time delay (1981), Oscillation theorems of n th-order functional-differential equations with forcing terms (1985), Cone-valued Lyapunov functions and stability of non-linear boundary value problems (1997), and An interval analytic method in constructive existence theorems for initial value problems (2002).
• He has published over 70 papers including On the stability of a nonhomogeneous differential equation of the fourth order (1972), Finite time controllability of nonlinear control processes (1975), On the null-controllability of nonlinear delay systems with restrained controls (1980), Global null controllability of nonlinear delay equations with controls in a compact set (1987), Optimal control of the growth of income of nations (1994), On the controllability of nonlinear economic systems with delay: the Italian example (1998), and Goodness through optimal dynamics of the wealth of nations (2003).
• He has published around 20 papers including Sur la resolution de l'equation integrale d'Ambarzumian (1965), Une condition necessaire pour qu'une fonction soit caracteristique (1966), Sur quelques proprietes des espaces homogenes moyennables (1971), Quelques applications associees a l'application de Reiter (1981), Sur la cohomologie des algebres de Malπcev.
• He wrote Etudes des Liens Entre les Equations Differentielles Stochastiques Retrogrades et les Equations aux Derivees Partielles (2003).
• Thesis title: Computation of steady two-dimensional transonic flows by an integral equation method.
• He has published around 30 papers including On notions of Markov property (1977), A characterization of Markovian homogeneous multicomponent Gaussian fields (1980), Quantum stochastic integration in certain partial *-algebras (1986), The functional Ito formula in quantum stochastic calculus (1990), Algebraic representation theory of partial algebras (2001), and Topological solutions of noncommutative stochastic differential equations (2007).
• Thesis title: Retarded Functional Differential Equations (A Global Point of View).
• He has published the book Stochastic functional differential equations (1984) and around 50 papers including Separation of variables (an abstract approach) (1974), The infinitesimal generator of a stochastic functional-differential equation (1982), An extension of Hormander's theorem for infinitely degenerate second-order operators (1995), Discrete-time approximations of stochastic delay equations: the Milstein scheme (2004), Sobolev differentiable stochastic flows for SDEs with singular coefficients: applications to the transport equation (2015), and An option pricing model with memory (2017).
• Thesis title: Numerical Treatment of the Time Variable in Parabolic Equations.
• He has published over 50 papers including On the stability of the planar motions of a rigid body around a fixed point in a Newtonian force fieldn(Russian) (1981), Reduction of the equation of motion of a rigid body about a fixed point to one differential equation (1984), Generalized natural mechanical systems of two degrees of freedom with quadratic integrals (1992), On the stability of motion of a gyrostat about a fixed point under the action of non-symmetric fields (1999), On certain two-dimensional conservative mechanical systems with a cubic second integral (2002), The master integrable two-dimensional system with a quartic second integral (2006), and Regular precession of a rigid body (gyrostat) acted upon by an irreducible combination of three classical fields (2017).
• Thesis title: Numerical Methods for the Solution of the Shallow-Water Equations in Meteorology.
• He has over 200 publications including A linear ADI method for the shallow-water equations (1980), A Numerov-Galerkin technique applied to a finite-element shallow-water equations model with enforced conservation of integral invariants and selective lumping (1983), Analysis of the Turkel-Zwas scheme for the two-dimensional shallow water equations in spherical coordinates (1997), On a posteriori pointwise error estimation using adjoint temperature and Lagrange remainder (2005), Reduced-order modelling of an adaptive mesh ocean model (2009), Non-parametric calibration of the local volatility surface for European options using a second-order Tikhonov regularization (2014), and Efficiency of randomised dynamic mode decomposition for reduced order modelling (2018).
• He has over 30 publications including On necessary and sufficient conditions for the existence of Caratheodory solutions of ordinary differential equations (1977), On the location of the essential spectra and regularity fields of complex Sturm-Liouville operators (1980), The theory ofnJ-selfadjoint extensions ofnJ-symmetric operators (1985), On the commutativity of certain quasidifferential expressions (1990), and Self-adjointness for the Weyl problem under an energy norm (1995).
• Thesis title: Konstruktion von Losungen nichtlinearer elliptischer Differential-gleichungssysteme erster Ordnung in der Ebene durch komplexe Methoden im Sobolev - Raum W sub {1,p} (G) (insbesondere Losung des Dirichlet - Randwertproblems mit Randwerten aus dem Slobodeckij - Raum W sub {s,p} (L), s = 1 - 1/p) [Construction of Solutions of Nonlinear Systems of Elliptic Differential Equations of First Order in the Plane Using Complex Methods in the Sobolev Space W sub{1, p} (G) (in Particular the Solution of the Dirichlet Boundary Value Problem with Boundary Values from the Sobolev Space W sub {s, p}(L), s = 1 - 1/p)].
• He has published around 30 papers including On the L_pnnorms of some integral operators (1983), On the Hilbert boundary value problem for holomorphic function in Sobolev spaces (1988), On the solution of a mixed boundary value problem for an elliptic differential equation in Sobolev spaces (1991), and On the existence of a solution in weighted Sobolev space to the Riemann-Hilbert problem for an elliptic system with piecewise continuous boundary data (2006).
• Thesis title: Remarques sur les Equations Differentielles Abstraites [Remarks on abstract differential equations].
• He has over 200 publications including the papers On almost-periodic perturbation of exponentially dichotomic abstract differential equations (1982), Some remarks on asymptotically almost automorphic functions (1988), On almost automorphic differential equations in Banach spaces (1999), On some perturbations of some abstract differential equations (2003), On the topological structure of almost automorphic and asymptotically almost automorphic solutions of differential and integral equations in abstract spaces (2004), Almost automorphic solutions for partial functional differential equations with infinite delay (2007), Existence of mild solutions of some semilinear neutral fractional functional evolution equations with infinite delay (2010), Almost automorphic functions of ordernnnand applications to dynamic equations on time scales (2014), and Recurrence of bounded solutions to a semilinear integro-differential equation perturbed by Levy noise (2018).
• His papers include On testing against restricted alternatives for Penrose model (1985), Parameter selection for a delay equation (1990), The optimal classification rule for exponential populations (1993), Statistical tables for class work and examination (1995), and Equations for generating normally distributed random variables with specified intercorrelation (2010).
• He had published around 30 papers including Determinant sur des anneaux filtres (1981), Reseaux sur des anneaux filtres (1982), Sur le groupe de Whitehead et les systemes d'equations aux derivees partielles (1984), Sur l'effectivite du lemme du vecteur cyclique (1988), A new inversion formula for a polynomial map in two variables (1991), On separable algebras over a U.F.D.