13.3 CONCLUDING REMARKS
The properties of the Laplace transform derived in this section can sometimesbe useful in finding the Laplace transforms of particular functions.
Find the Laplace transform off(t)=tsinbt.Although we could calculate the Laplace transform directly, we can use (13.62) to give
f ̄(s)=(−1)d
dsL[sinbt]=−d
ds(
b
s^2 +b^2)
=
2 bs
(s^2 +b^2 )^2, fors> 0 .13.3 Concluding remarksIn this chapter we have discussed Fourier and Laplace transforms in some detail.
Both are examples ofintegral transforms, which can be considered in a more
general context.
A general integral transform of a functionf(t) takes the formF(α)=∫baK(α, t)f(t)dt, (13.65)whereF(α) is the transform off(t) with respect to thekernelK(α, t), andαis
the transform variable. For example, in the Laplace transform caseK(s, t)=e−st,
a=0,b=∞.
Very often the inverse transform can also be written straightforwardly andwe obtain a transform pair similar to that encountered in Fourier transforms.
Examples of such pairs are
(i) the Hankel transformF(k)=∫∞0f(x)Jn(kx)xdx,f(x)=∫∞0F(k)Jn(kx)kdk,where theJnare Bessel functions of ordern,and
(ii) the Mellin transformF(z)=∫∞0tz−^1 f(t)dt,f(t)=1
2 πi∫i∞−i∞t−zF(z)dz.Although we do not have the space to discuss their general properties, thereader should at least be aware of this wider class of integral transforms.