Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

25.5 INVERSE LAPLACE TRANSFORM


Γ R ΓΓR R


L L L


(a) (b) (c)

Figure 25.7 Some contour completions for the integration pathLof the
inverse Laplace transform. For details of when each is appropriate see the
main text.

plausible:


f(x)=

1
2 πi

∫λ+i∞

λ−i∞

ds esx

∫∞

0

e−suf(u)du, Re(s)> 0 ,i.e.λ> 0 ,

=

1
2 πi

∫∞

0

du f(u)

∫λ+i∞

λ−i∞

es(x−u)ds

=

1
2 πi

∫∞

0

du f(u)

∫∞

−∞

eλ(x−u)eip(x−u)i dp, puttings=λ+ip,

=

1
2 π

∫∞

0

f(u)eλ(x−u) 2 πδ(x−u)du

=

{
f(x) x≥ 0 ,

0 x< 0.

(25.26)

Our main purpose here is to demonstrate the use of contour integration. To


employ it in the evaluation of the line integral (25.25), the pathLmust be made


part of a closed contour in such a way that the contribution from the completion


either vanishes or is simply calculable.


A typical completion is shown in figure 25.7(a) and would be appropriate if
̄f(s) had a finite number of poles. For more complicated cases, in whichf ̄(s)has


an infinite sequence of poles but all to the left ofLas in figure 25.7(b), a sequence


of circular-arc completions that pass between the poles must be used andf(x)is


obtained as a series. If ̄f(s) is a multivalued function then a cut plane is needed


and a contour such as that shown in figure 25.7(c) might be appropriate.


We consider here only the simple case in which the contour in figure 25.7(a)

is used; we refer the reader to the exercises at the end of the chapter for others.

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