Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

18.5 BESSEL FUNCTIONS


Prove the expression (18.91).

If we multiply (18.90) byxJν(αmx) and integrate fromx=0tox=bthen we obtain
∫b


0

xJν(αmx)f(x)dx=

∑∞


n=0

cn

∫b

0

xJν(αmx)Jν(αnx)dx

=cm

∫b

0

Jν^2 (αmx)xdx

=^12 cmb^2 J′^2 ν(αmb)=^12 cmb^2 J^2 ν+1(αmb),

where in the last two lines we have used (18.88) withαm=α=β=αn, (18.89), the fact
thatJν(αmb) = 0 and (18.95), which is proved below.


Recurrence relations

The recurrence relations enjoyed by Bessel functions of the first kind,Jν(x), can


be derived directly from the power series definition (18.79).


Prove the recurrence relation
d
dx

[xνJν(x)] =xνJν− 1 (x). (18.92)

From the power series definition (18.79) ofJν(x)weobtain


d
dx

[xνJν(x)] =

d
dx

∑∞


n=0

(−1)nx^2 ν+2n
2 ν+2nn!Γ(ν+n+1)

=


∑∞


n=0

(−1)nx^2 ν+2n−^1
2 ν+2n−^1 n!Γ(ν+n)

=xν

∑∞


n=0

(−1)nx(ν−1)+2n
2 (ν−1)+2nn!Γ((ν−1) +n+1)

=xνJν− 1 (x).

It may similarly be shown that
d
dx

[x−νJν(x)] =−x−νJν+1(x). (18.93)

From (18.92) and (18.93) the remaining recurrence relations may be derived.


Expanding out the derivative on the LHS of (18.92) and dividing through by


xν−^1 , we obtain the relation


xJν′(x)+νJν(x)=xJν− 1 (x). (18.94)

Similarly, by expanding out the derivative on the LHS of (18.93), and multiplying


through byxν+1, we find


xJν′(x)−νJν(x)=−xJν+1(x). (18.95)

Adding (18.94) and (18.95) and dividing through byxgives


Jν− 1 (x)−Jν+1(x)=2Jν′(x). (18.96)
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