Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

APPLICATIONS OF COMPLEX VARIABLES


Ideally, we would like the contribution to the integral from the circular arc Γ to


tend to zero as its radiusR→∞. Using a modified version of Jordan’s lemma,


it may be shown that this is indeed the case if there exist constantsM>0and


α>0 such that on Γ


| ̄f(s)|≤

M

.

Moreover, this condition always holds when ̄f(s)hastheform


̄f(s)=P(s)
Q(s)

,

whereP(s)andQ(s) are polynomials and the degree ofQ(s) is greater than that


ofP(s).


When the contribution from the part-circle Γ tends to zero asR→∞,we

have from the residue theorem that the inverse Laplace transform (25.25) is given


simply by


f(t)=

∑(
residues of ̄f(s)esxat all poles

)

. (25.27)


Find the functionf(x)whose Laplace transform is

̄f(s)= s
s^2 −k^2

,


wherekis a constant.

It is clear that ̄f(s) is of the form required for the integral over the circular arc Γ to tend
to zero asR→∞, and so we may use the result (25.27) directly. Now


̄f(s)esx= se

sx
(s−k)(s+k)

,


and thus has simple poles ats=kands=−k. Using (24.57) the residues at each pole can
be easily calculated as


R(k)=

kekx
2 k

and R(−k)=

ke−kx
2 k

.


Thus the inverse Laplace transform is given by


f(x)=^12

(


ekx+e−kx

)


=coshkx.

This result may be checked by computing the forward transform of coshkx.


Sometimes a little more care is required when deciding in which half-plane to

close the contourC.


Find the functionf(x)whose Laplace transform is

̄f(s)=^1
s

(e−as−e−bs),

whereaandbare fixed and positive, withb>a.

From (25.25) we have the integral


f(x)=

1


2 πi

∫λ+i∞

λ−i∞

e(x−a)s−e(x−b)s
s

ds. (25.28)
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