Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

16.2 SERIES SOLUTIONS ABOUT AN ORDINARY POINT


Equation Regular Essential
singularities singularities
Hypergeometric
z(1−z)y′′+[c−(a+b+1)z]y′−aby=0 0 , 1 ,∞ —
Legendre
(1−z^2 )y′′− 2 zy′+(+1)y=0 − 1 , 1 ,∞ —
Associated Legendre

(1−z^2 )y′′− 2 zy′+

[


(+1)−


m^2
1 −z^2

]


y=0 − 1 , 1 ,∞ —

Chebyshev
(1−z^2 )y′′−zy′+ν^2 y=0 − 1 , 1 ,∞ —
Confluent hypergeometric
zy′′+(c−z)y′−ay=0 0 ∞
Bessel
z^2 y′′+zy′+(z^2 −ν^2 )y=0 0 ∞
Laguerre
zy′′+(1−z)y′+νy=0 0 ∞
Associated Laguerre
zy′′+(m+1−z)y′+(ν−m)y=0 0 ∞
Hermite
y′′− 2 zy′+2νy=0 — ∞
Simple harmonic oscillator
y′′+ω^2 y=0 — ∞

Table 16.1 Important second-order linear ODEs in the physical sciences and
engineering.

Table 16.1 lists the singular points of several second-order linear ODEs that

play important roles in the analysis of many problems in physics and engineering.


A full discussion of the solutions to each of the equations in table 16.1 and their


properties is left until chapter 18. We now discuss the general methods by which


series solutions may be obtained.


16.2 Series solutions about an ordinary point

Ifz=z 0 is an ordinary point of (16.7) then it may be shown thateverysolution


y(z) of the equation is also analytic atz=z 0. From now on we will takez 0 as the


origin, i.e.z 0 = 0. If this is not already the case, then a substitutionZ=z−z 0


will make it so. Since every solution is analytic,y(z) can be represented by a

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