Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

18.9 HERMITE FUNCTIONS


H 0


H 1


H 2


H 3


− 1. 5 − 1 − 0. 5 0.^511.^5


5


10


− 5


− 10


x

Figure 18.8 The first four Hermite polynomials.

an+2=an+4=···= 0, and so one solution of Hermite’s equation is a polynomial


of ordern. For evenn, it is conventional to choosea 0 =(−1)n/^2 n!/(n/2)!, whereas


for oddnone takesa 1 =(−1)(n−1)/^22 n!/[^12 (n−1)]!. These choices allow a general


solution to be written as


Hn(x)=(2x)n−n(n−1)(2x)n−^1 +

n(n−1)(n−2)(n−3)
2!

(2x)n−^4 −···(18.128)

=

[∑n/2]

m=0

(−1)m

n!
m!(n− 2 m)!

(2x)n−^2 m, (18.129)

whereHn(x) is called thenthHermite polynomialand the notation [n/2] denotes


the integer part ofn/2. We note in particular thatHn(−x)=(−1)nHn(x). The


first few Hermite polynomials are given by


H 0 (x)=1,H 3 (x)=8x^2 − 12 x,

H 1 (x)=2x, H 4 (x)=16x^4 − 48 x^2 +12,

H 2 (x)=4x^2 − 2 ,H 5 (x)=32x^5 − 160 x^3 + 120x.

The functionsH 0 (x),H 1 (x),H 2 (x)andH 3 (x) are plotted in figure 18.8.

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