Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

SPECIAL FUNCTIONS


Finally, subtracting (18.95) from (18.94) and dividing byxgives


Jν− 1 (x)+Jν+1(x)=

2 ν
x

Jν(x). (18.97)

Given thatJ 1 / 2 (x)=(2/πx)^1 /^2 sinxand thatJ− 1 / 2 (x)=(2/πx)^1 /^2 cosx,expressJ 3 / 2 (x)
andJ− 3 / 2 (x)in terms of trigonometric functions.

From (18.95) we have


J 3 / 2 (x)=

1


2 x

J 1 / 2 (x)−J′ 1 / 2 (x)

=


1


2 x

(


2


πx

) 1 / 2


sinx−

(


2


πx

) 1 / 2


cosx+

1


2 x

(


2


πx

) 1 / 2


sinx

=


(


2


πx

) 1 / 2 (


1


x

sinx−cosx

)


.


Similarly, from (18.94) we have


J− 3 / 2 (x)=−

1


2 x

J− 1 / 2 (x)+J−′ 1 / 2 (x)

=−


1


2 x

(


2


πx

) 1 / 2


cosx−

(


2


πx

) 1 / 2


sinx−

1


2 x

(


2


πx

) 1 / 2


cosx

=


(


2


πx

) 1 / 2 (



1


x

cosx−sinx

)


.


We see that, by repeated use of these recurrence relations, all Bessel functionsJν(x)ofhalf-
integer order may be expressed in terms of trigonometric functions. From their definition
(18.81), Bessel functions of the second kind,Yν(x), of half-integer order can be similarly
expressed.


Finally, we note that the relations (18.92) and (18.93) may be rewritten in

integral form as



xνJν− 1 (x)dx=xνJν(x),

x−νJν+1(x)dx=−x−νJν(x).

Ifνis an integer, the recurrence relations of this section may be proved using

the generating function for Bessel functions discussed below. It may be shown


that Bessel functions of the second kind,Yν(x), also satisfy the recurrence relations


derived above.


Generating function

The Bessel functionsJν(x), whereν=nis an integer, can be described by a


generating function in a way similar to that discussed for Legendre polynomials

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