Mathematical Methods for Physics and Engineering : A Comprehensive Guide

COMPLEX VARIABLES

formula (24.56) withm= 2. Choosing the latter method and denoting the integrand by
f(z), we have

d

dz

[z^2 f(z)] =

d

dz

[

z^4 +1

(z−a/b)(z−b/a)

]

=

(z−a/b)(z−b/a)4z^3 −(z^4 +1)[(z−a/b)+(z−b/a)]

(z−a/b)^2 (z−b/a)^2

.

Now settingz= 0 and applying (24.56), we find

R(0) =

a

b

+

b

a

.

For the simple pole atz=a/b, equation (24.57) gives the residue as

R(a/b) = lim

z→(a/b)

[

(z−a/b)f(z)

]

=

(a/b)^4 +1

(a/b)^2 (a/b−b/a)

=−

a^4 +b^4

ab(b^2 −a^2 )

.

Therefore by the residue theorem

I=2πi×

i

2 ab

[

a^2 +b^2

ab

−

a^4 +b^4

ab(b^2 −a^2 )

]

=

2 πa^2

b^2 (b^2 −a^2 )

.

24.13.2 Some infinite integrals

We next consider the evaluation of an integral of the form
∫∞

−∞

f(x)dx,

wheref(z) has the following properties:

(i)f(z) is analytic in the upper half-plane, Imz≥0, except for a finite number

of poles, none of which is on the real axis;

(ii) on a semicircle Γ of radiusR(figure 24.14),Rtimes the maximum of|f|

on Γ tends to zero asR→∞(a sufficient condition is thatzf(z)→0as

|z|→∞);

(iii)

∫ 0

−∞f(x)dxand

∫∞

0 f(x)dxboth exist.

Since ∣
∣
∣
∣

∫

Γ

f(z)dz

∣

∣

∣

∣≤^2 πR×(maximum of|f|on Γ),

condition (ii) ensures that the integral along Γ tends to zero asR→∞, after

which it is obvious from the residue theorem that the required integral is given

by
∫∞

−∞

f(x)dx=2πi×(sum of the residues at poles with Imz>0).

(24.68)