Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

13.2 LAPLACE TRANSFORMS


A similar result may be obtained for two-dimensional Fourier transforms in

whichf(r)=f(ρ), i.e.f(r) is independent of azimuthal angleφ. In this case, using


the integral representation of the Bessel functionJ 0 (x) given at the very end of


subsection 18.5.3, we find


̃f(k)=^1
2 π

∫∞

0

2 πρf(ρ)J 0 (kρ)dρ. (13.52)

13.2 Laplace transforms

Often we are interested in functionsf(t) for which the Fourier transform does not


exist becausef→0ast→∞, and so the integral defining ̃fdoes not converge.


This would be the case for the functionf(t)=t, which does not possess a Fourier


transform. Furthermore, we might be interested in a given function only fort>0,


for example when we are given the value att= 0 in an initial-value problem.


This leads us to consider the Laplace transform,f ̄(s)orL[f(t)],off(t), which


is defined by


f ̄(s)≡

∫∞

0

f(t)e−stdt, (13.53)

provided that the integral exists. We assume here thatsis real, but complex values


would have to be considered in a more detailed study. In practice, for a given


functionf(t) there will be some real numbers 0 such that the integral in (13.53)


exists fors>s 0 but diverges fors≤s 0.


Through (13.53) we define alineartransformationLthat converts functions

of the variabletto functions of a new variables:


L[af 1 (t)+bf 2 (t)]=aL[f 1 (t)]+bL[f 2 (t)]=af ̄ 1 (s)+bf ̄ 2 (s). (13.54)

Find the Laplace transforms of the functions(i)f(t)=1,(ii)f(t)=eat,(iii)f(t)=tn,
forn=0, 1 , 2 ,....

(i) By direct application of the definition of a Laplace transform (13.53), we find

L[ 1 ]=

∫∞


0

e−stdt=

[


− 1


s

e−st

]∞


0

=


1


s

, ifs> 0 ,

where the restrictions>0 is required for the integral to exist.
(ii) Again using (13.53) directly, we find

f ̄(s)=

∫∞


0

eate−stdt=

∫∞


0

e(a−s)tdt

=


[


e(a−s)t
a−s

]∞


0

=


1


s−a

ifs>a.
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