Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

24.14 Exercises


We have seen that



Γand


γvanish, and if we denotezbyxalong the lineABthen it
has the valuez=xexp 2πialong the lineDC(note that exp 2πimust not be set equal to
1 until after the substitution forzhas been made in



DC). Substituting these expressions,
∫∞

0

dx
(x+a)^3 x^1 /^2

+


∫ 0



dx
[xexp 2πi+a]^3 x^1 /^2 exp(^122 πi)

=


3 π
4 a^5 /^2

.


Thus (


1 −

1


expπi

)∫∞


0

dx
(x+a)^3 x^1 /^2

=


3 π
4 a^5 /^2

and


I=

1


2


×


3 π
4 a^5 /^2

.


Several other examples of integrals of multivalued functions around a variety

of contours are included in the exercises that follow.


24.14 Exercises

24.1 Find an analytic function ofz=x+iywhose imaginary part is


(ycosy+xsiny)expx.

24.2 Find a functionf(z), analytic in a suitable part of the Argand diagram, for which


Ref=

sin 2x
cosh 2y−cos 2x

.


Wherearethesingularitiesoff(z)?
24.3 Find the radii of convergence of the following Taylor series:


(a)

∑∞


n=2

zn
lnn

, (b)

∑∞


n=1

n!zn
nn

,


(c)

∑∞


n=1

znnlnn, (d)

∑∞


n=1

(


n+p
n

)n 2
zn,withpreal.

24.4 Find the Taylor series expansion about the origin of the functionf(z) defined by


f(z)=

∑∞


r=1

(−1)r+1sin

(pz

r

)


,


wherepis a constant. Hence verify thatf(z) is a convergent series for allz.
24.5 Determine the types of singularities (if any) possessed by the following functions
atz=0andz=∞:
(a) (z−2)−^1 , (b) (1 +z^3 )/z^2 , (c) sinh(1/z),
(d)ez/z^3 , (e)z^1 /^2 /(1 +z^2 )^1 /^2.


24.6 Identify the zeros, poles and essential singularities of the following functions:


(a) tanz, (b) [(z−2)/z^2 ] sin[1/(1−z)], (c) exp(1/z),
(d) tan(1/z), (e)z^2 /^3.
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