Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

SPECIAL FUNCTIONS


where, in the second equality, we have expanded the RHS using the binomial theorem. On
equating coefficients ofhn, we immediately obtain


Lmn(0) =

(n+m)!
n!m!

.


Recurrence relations

The various recurrence relations satisfied by the associated Laguerre polynomials


may be derived by differentiating the generating function (18.123) with respect to


either or both ofxandh, or by differentiating with respect toxthe recurrence


relations obeyed by the ordinary Laguerre polynomials, discussed in section 18.7.1.


Of the many recurrence relations satisfied by the associated Laguerre polynomials,


two of the most useful are as follows:


(n+1)Lmn+1(x)=(2n+m+1−x)Lmn(x)−(n+m)Lmn− 1 (x), (18.124)

x(Lmn)′(x)=nLmn(x)−(n+m)Lmn− 1 (x). (18.125)

For proofs of these relations the reader is referred to exercise 18.7.


18.9 Hermite functions

Hermite’s equation has the form


y′′− 2 xy′+2νy=0, (18.126)

and has an essential singularity atx=∞. The parameterνis a given real


number, although it nearly always takes an integer value in physical applications.


The Hermite equation appears in the description of the wavefunction of the


harmonic oscillator. Any solution of (18.126) is called aHermite function.


Sincex= 0 is an ordinary point of the equation, we may find two linearly

independent solutions in the form of a power series (see section 16.2):


y(x)=

∑∞

m=0

amxm. (18.127)

Substituting this series into (18.107) yields


∑∞

m=0

[(m+1)(m+2)am+2+2(ν−m)am]xm=0.

Demanding that the coefficient of each power ofxvanishes, we obtain the


recurrence relation


am+2=−

2(ν−m)
(m+1)(m+2)

am.

As mentioned above, in nearly all physical applications, the parameterνtakes

integer values. Therefore, ifν=n,wherenis a non-negative integer, we see that

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