Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

18.7 LAGUERRE FUNCTIONS


Prove that the expression (18.112) yields thenth Laguerre polynomial.

Evaluating thenth derivative in (18.112) using Leibnitz’ theorem, we find


Ln(x)=

ex
n!

∑n

r=0

nCrd

rxn
dxr

dn−re−x
dxn−r

=


ex
n!

∑n

r=0

n!
r!(n−r)!

n!
(n−r)!

xn−r(−1)n−re−x

=


∑n

r=0

(−1)n−r

n!
r!(n−r)!(n−r)!

xn−r.

Relabelling the summation using the indexm=n−r,weobtain


Ln(x)=

∑n

m=0

(−1)m

n!
(m!)^2 (n−m)!

xm,

which is precisely the expression (18.111) for thenth Laguerre polynomial.


Mutual orthogonality

In section 17.4, we noted that Laguerre’s equation could be put into Sturm–


Liouville form withp=xe−x,q=0,λ=νandρ=e−x, and its natural interval


is thus [0,∞]. Since the Laguerre polynomialsLn(x)aresolutionsoftheequation


and are regular at the end-points, they must be mutually orthogonal over this


interval with respect to the weight functionρ=e−x,i.e.
∫∞


0

Ln(x)Lk(x)e−xdx=0 ifn=k.

This result may also be proved directly using the Rodrigues’ formula (18.112).


Indeed, the normalisation, whenk=n, is most easily found using this method.


Show that

I≡

∫∞


0

Ln(x)Ln(x)e−xdx=1. (18.113)

Using the Rodrigues’ formula (18.112), we may write


I=

1


n!

∫∞


0

Ln(x)

dn
dxn

(xne−x)dx=

(−1)n
n!

∫∞


0

dnLn
dxn

xne−xdx,

where, in the second equality, we have integrated by partsntimes and used the fact that the
boundary terms all vanish. WhendnLn/dxnis evaluated using (18.111), only the derivative
of them=nterm survives and that has the value [ (−1)nn!n!]/[(n!)^2 0!] = (−1)n. Thus
we have


I=

1


n!

∫∞


0

xne−xdx=1,

where, in the second equality, we use the expression (18.153) defining the gamma function
(see section 18.12).

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