Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

COMPLEX VARIABLES


y

x

A B


C D


Γ


γ

Figure 24.16 A typical cut-plane contour for use with multivalued functions
that have a single branch point located at the origin.

located at the origin is shown in figure 24.16. Here Γ is a large circle of radiusR


andγis a small one of radiusρ, both centred on the origin. Eventually we will


letR→∞andρ→0.


The success of the method is due to the fact that because the integrand is

multivalued, its values along the two linesABandCDjoiningz=ρtoz=R


arenotequal and opposite although both are related to the corresponding real


integral. Again an example provides the best explanation.


Evaluate

I=

∫∞


0

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

,a> 0.

We consider the integrandf(z)=(z+a)−^3 z−^1 /^2 and note that|zf(z)|→0onthetwo
circles asρ→0andR→∞. Thus the two circles make no contribution to the contour
integral.
The only pole of the integrand inside the contour is atz=−a(and is of order 3).
To determine its residue we putz=−a+ξand expand (noting that (−a)^1 /^2 equals
a^1 /^2 exp(iπ/2) =ia^1 /^2 ):


1
(z+a)^3 z^1 /^2

=


1


ξ^3 ia^1 /^2 (1−ξ/a)^1 /^2

=

1


iξ^3 a^1 /^2

(


1+


1


2


ξ
a

+


3


8


ξ^2
a^2

+···


)


.


The residue is thus− 3 i/(8a^5 /^2 ).
The residue theorem (24.61) now gives


AB

+



Γ

+



DC

+



γ

=2πi

(


− 3 i
8 a^5 /^2

)


.

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