Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

EIGENFUNCTION METHODS FOR DIFFERENTIAL EQUATIONS


set consists of those functionsyifor which


Lyi(x)=λiyi(x), (17.2)

whereλiis a constant (and which satisfy the boundary conditions), then a distinct


advantage may be obtained from the manoeuvre because all the differentiation


will have disappeared from (17.1).


Equation (17.2) is clearly reminiscent of the equation satisfied by theeigenvec-

torsxiof a linear operatorA, namely


Axi=λixi, (17.3)

whereλiis a constant and is called theeigenvalueassociated withxi. By analogy,


in the context of differential equations a functionyi(x) satisfying (17.2) is called


aneigenfunctionof the operatorL(under the imposed boundary conditions) and


λiis then called the eigenvalue associated with the eigenfunctionyi(x). Clearly,


the eigenfunctionsyi(x)ofLare only determined up to an arbitrary scale factor


by (17.2).


Probably the most familiar equation of the form (17.2) is that which describes

a simple harmonic oscillator, i.e.


Ly≡−

d^2 y
dt^2

=ω^2 y, whereL≡−d^2 /dt^2. (17.4)

Imposing the boundary condition that the solution is periodic with periodT,


the eigenfunctions in this case are given byyn(t)=Aneiωnt,whereωn=2πn/T,


n=0,± 1 ,± 2 ,...and theAnare constants. The eigenvalues areω^2 n=n^2 ω^21 =


n^2 (2π/T)^2. (Sometimesωnis referred to as the eigenvalue of this equation, but


we will avoid such confusing terminology here.)


We may discuss a somewhat wider class of differential equations by considering

a slightly more general form of (17.2), namely


Lyi(x)=λiρ(x)yi(x), (17.5)

whereρ(x)isaweight function. In many applicationsρ(x) is unity for allx,in


which case (17.2) is recovered; in general, though, it is a function determined by


the choice of coordinate system used in describing a particular physical situation.


The only requirement onρ(x) is that it is real and does not change sign in the


rangea≤x≤b, so that it can, without loss of generality, be taken to be non-


negative throughout; of course,ρ(x) must be the same function for all values of


λi. A functionyi(x) that satisfies (17.5) is called an eigenfunction of the operator


Lwith respect to the weight functionρ(x).


This chapter will not cover methods used to determine the eigenfunctions of

(17.2) or (17.5), since we have discussed those in previous chapters, but, rather, will


use the properties of the eigenfunctions to solve inhomogeneous equations of the


form (17.1). We shall see later that the sets of eigenfunctionsyi(x) of a particular

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