Mathematical Methods for Physics and Engineering : A Comprehensive Guide

COMPLEX VARIABLES

whereais a finite, non-zero complex number. We note that if the above limit is

equal to zero, thenz=z 0 is a pole of order less thann,orf(z) is analytic there;

if the limit is infinite then the pole is of an order greater thann. It may also be

shown that iff(z) has a pole atz=z 0 ,then|f(z)|→∞asz→z 0 from any

direction in the Argand diagram.§If no finite value ofncan be found such that

(24.24) is satisfied, thenz=z 0 is called anessential singularity.

Find the singularities of the functions

(i)f(z)=

1

1 −z

−

1

1+z

, (ii)f(z)=tanhz.

(i) If we writef(z)as

f(z)=

1

1 −z

−

1

1+z

=

2 z

(1−z)(1 +z)

,

we see immediately from either (24.23) or (24.24) thatf(z) has poles of order 1 (orsimple
poles)atz=1andz=−1.
(ii) In this case we write

f(z)=tanhz=

sinhz

coshz

=

expz−exp(−z)

expz+exp(−z)

.

Thusf(z) has a singularity when expz=−exp(−z) or, equivalently, when

expz=exp[i(2n+1)π]exp(−z),

wherenis any integer. Equating the arguments of the exponentials we findz=(n+^12 )πi,
for integern.
Furthermore, using l’Hopital’s rule (see chapter 4) we haveˆ

lim

z→(n+^12 )πi

{

[z−(n+^12 )πi]sinhz

coshz

}

= lim

z→(n+^12 )πi

{

[z−(n+^12 )πi]coshz+sinhz

sinhz

}

=1.

Therefore, from (24.24), each singularity is a simple pole.

Another type of singularity exists at points for which the value off(z)takes

an indeterminate form such as 0/0 but limz→z 0 f(z) exists and is independent

of the direction from whichz 0 is approached. Such points are calledremovable

singularities.

Show thatf(z)=(sinz)/zhas a removable singularity atz=0.

It is clear thatf(z) takes the indeterminate form 0/0atz= 0. However, by expanding
sinzas a power series inz, we find

f(z)=

1

z

(

z−

z^3

3!

+

z^5

5!

−···

)

=1−

z^2

3!

+

z^4

5!

−···.

§Although perhaps intuitively obvious, this result really requires formal demonstration by analysis.