History of Functional Analysis presents functional analysis as a rather complex blend of algebra and topology, with its evolution influenced by the development of these two branches of mathematics. The book adopts a narrower definitionâone that is assumed to satisfy various algebraic and topological conditions. A moment of reflections shows that this already covers a large part of modern analysis, in particular, the theory of partial differential equations. This volume comprises nine chapters, the first of which focuses on linear differential equations and the Sturm-Liouville problem. The succeeding chapters go on to discuss the ""crypto-integral"" equations, including the Dirichlet principle and the Beer-Neumann method; the equation of vibrating membranes, including the contributions of Poincare and H.A. Schwarz's 1885 paper; and the idea of infinite dimension. Other chapters cover the crucial years and the definition of Hilbert space, including Fredholm's discovery and the contributions of Hilbert; duality and the definition of normed spaces, including the Hahn-Banach theorem and the method of the gliding hump and Baire category; spectral theory after 1900, including the theories and works of F. Riesz, Hilbert, von Neumann, Weyl, and Carleman; locally convex spaces and the theory of distributions; and applications of functional analysis to differential and partial differential equations. This book will be of interest to practitioners in the fields of mathematics and statistics.
Linear Differential Equations and the Sturm-Liouville Problem
§1 Differential Equations and Partial Differential Equations in the XVIIIth Century
Until around 1750, the notion of function of one variable was a very hazy one. The domain where it was defined was very seldom described with precision; it was tacitly assumed that around each point x0, the function was equal to a power series in x-x0 and its derivatives were obtained by taking the derivatives of each term of the series. To solve a differential equation of order n
(1)
one would therefore substitute in (1) for y and itâs derivatives a power series
and its derivatives, and identify the series on both sides, which would determine each ck, for k
n as a function of co, c1,âŠ, ckâ1; the solution thus depended on n arbitrary parameters c0,âŠ, cnâ1. The very few cases in which it was possible to write explicitly the solution by means of primitives of known functions (such as the linear equation yâČ = a(x)y + b(x) of order 1) were already known at the end of the XVIIth century.
After 1760 began the first general study of linear equations of arbitrary order
(2)
DâAlembert observed that the knowledge of a particular solution of the equation and of all solutions of the homogeneous equation L(y) = 0 yields by addition all solutions of (2). A little later, Lagrange [135, vol. I, p. 474] showed that the general solution of L(y) = 0 may be written
where the Ck are arbitrary constants, and the yk (1
k
n) particular solutions (which he tacitly assumed to be linearly independent). Then, by his famous method of âvariation of constantsâ [135, vol. IV, p. 159], he showed how to obtain also the solutions of (2) when the yk were known: the solution is written in the form
, where the zk are unknown functions, subject to n-1 linear relations
(3)
These conditions imply that
for 0
v
nâ1; replacing y by
in (2) and using the fact that the yk satisfy L(yk) = 0, one obtains for the zâk another linear equation
(4)
from which, by the Cramer formulas, one can compute the zâk (1
k
n) and the problem is thus reduced to computing their primitives.
Lagrange also introduced [135, vol. I, p. 471] the notion of adjoint of a linear differential operator L, which was to acquire great importance later: he showed that there exists a linear differential operator M satisfying an identity
(5)
where B is bilinear in (y, yâ,âŠ, y(nâ1)) and (z, zâ,âŠ, z(nâ1)), constituting a generalization of the classical âintegration by partsâ; he deduced from that formula that if a solution z of M(z) = 0 was known, solutions of L(y) = 0 could be obtained by solving an equation B(y, z) = Const, of order nâ1.
Partial differential equations were not considered until the middle of the XVIIIth century, in connection with problems of Mechanics or Physics and then they were of order 2 at least (see §2). The study of partial differential equations of first ord...
Table des matiĂšres
Cover image
Title page
Table of Contents
Copyright page
Introduction
Chapter I: Linear Differential Equations and the Sturm-Liouville Problem
Chapter II: The âCrypto-Integralâ Equations
Chapter III: The Equation Of Vibrating Membranes
Chapter IV: The Idea Of Infinite Dimension
Chapter V: The Crucial Years and the Definition of Hilbert Space
Chapter VI: Duality and the Definition of Normed Spaces
Chapter VII: Spectral Theory After 1900
Chapter VIII: Locally Convex Spaces and the Theory of Distributions
Chapter IX: Applications of Functional Analysis to Differential and Partial Differential Equations
References
Author Index
Subject Index
Normes de citation pour History of Functional Analysis
APA 6 Citation
Dieudonne, J. (1983). History of Functional Analysis ([edition unavailable]). Elsevier Science. Retrieved from https://www.perlego.com/book/1837156/history-of-functional-analysis-pdf (Original work published 1983)
Chicago Citation
Dieudonne, J. (1983) 1983. History of Functional Analysis. [Edition unavailable]. Elsevier Science. https://www.perlego.com/book/1837156/history-of-functional-analysis-pdf.
Harvard Citation
Dieudonne, J. (1983) History of Functional Analysis. [edition unavailable]. Elsevier Science. Available at: https://www.perlego.com/book/1837156/history-of-functional-analysis-pdf (Accessed: 15 October 2022).
MLA 7 Citation
Dieudonne, J. History of Functional Analysis. [edition unavailable]. Elsevier Science, 1983. Web. 15 Oct. 2022.
