Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

24.14 EXERCISES


24.14 Prove that, forα>0, the integral
∫∞


0

tsinαt
1+t^2

dt

has the value (π/2) exp(−α).
24.15 Prove that
∫∞


0

cosmx
4 x^4 +5x^2 +1

dx=

π
6

(


4 e−m/^2 −e−m

)


form> 0.

24.16 Show that the principal value of the integral
∫∞


−∞

cos(x/a)
x^2 −a^2

dx

is−(π/a)sin1.
24.17 The following is an alternative (and roundabout!) way of evaluating the Gaussian
integral.


(a) Prove that the integral of [exp(iπz^2 )]cosecπzaround the parallelogram with
corners± 1 / 2 ±Rexp(iπ/4) has the value 2i.
(b) Show that the parts of the contour parallel to the real axis do not contribute
whenR→∞.
(c) Evaluate the integrals along the other two sides by puttingz′=rexp(iπ/4)
and working in terms ofz′+^12 andz′−^12. Hence, by lettingR→∞show
that
∫∞

−∞

e−πr

2
dr=1.

24.18 By applying the residue theorem around a wedge-shaped contour of angle 2π/n,
with one side along the real axis, prove that the integral
∫∞


0

dx
1+xn

,


wherenis real and≥2, has the value (π/n)cosec (π/n).
24.19 Using a suitable cut plane, prove that ifαis real and 0<α<1then
∫∞


0

x−α
1+x

dx

has the valueπcosecπα.
24.20 Show that ∫


0

lnx
x^3 /^4 (1 +x)

dx=−


2 π^2.

24.21 By integrating a suitable function around a large semicircle in the upper half-
plane and a small semicircle centred on the origin, determine the value of


I=


∫∞


0

(lnx)^2
1+x^2

dx

and deduce, as a by-product of your calculation, that
∫∞

0

lnx
1+x^2

dx=0.
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