Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

SPECIAL FUNCTIONS


which on collecting terms gives


∑∞

n=0

{(n+2)(n+1)an+2−[n(n+1)−(+1)]an}xn=0.

The recurrence relation is therefore


an+2=

[n(n+1)−(+1)]
(n+1)(n+2)

an, (18.2)

forn=0, 1 , 2 ,.... If we choosea 0 = 1 anda 1 = 0 then we obtain the solution


y 1 (x)=1−(+1)

x^2
2!

+(−2)(+1)(+3)

x^4
4!

−···, (18.3)

whereas on choosinga 0 = 0 anda 1 = 1 we find a second solution


y 2 (x)=x−(−1)(+2)

x^3
3!

+(−3)(−1)(+2)(+4)

x^5
5!

−···. (18.4)

By applying the ratio test to these series (see subsection 4.3.2), we find that both


series converge for|x|<1, and so their radius of convergence is unity, which


(as expected) is the distance to the nearest singular point of the equation. Since


(18.3) contains only even powers ofxand (18.4) contains only odd powers, these


two solutions cannot be proportional to one another, and are therefore linearly


independent. Hence, the general solution to (18.1) for|x|<1is


y(x)=c 1 y 1 (x)+c 2 y 2 (x).

18.1.1 Legendre functions for integer

In many physical applications the parameterin Legendre’s equation (18.1) is


an integer, i.e.=0, 1 , 2 ,.... In this case, the recurrence relation (18.2) gives


a+2=

[(+1)−(+1)]
(+1)(+2)

a=0,

i.e. the series terminates and we obtain a polynomial solution of order.In


particular, ifis even, theny 1 (x) in (18.3) reduces to a polynomial, whereas ifis


oddthesameistrueofy 2 (x) in (18.4). These solutions (suitably normalised) are


called theLegendre polynomialsof order; they are writtenP(x) and are valid


for all finitex. It is conventional to normaliseP(x) in such a way thatP(1) = 1,


and as a consequenceP(−1) = (−1). The first few Legendre polynomials are


easily constructed and are given by


P 0 (x)=1, P 1 (x)=x,

P 2 (x)=^12 (3x^2 −1), P 3 (x)=^12 (5x^3 − 3 x),

P 4 (x)=^18 (35x^4 − 30 x^2 +3), P 5 (x)=^18 (63x^5 − 70 x^3 +15x).
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