23.4 CLOSED-FORM SOLUTIONS
23.4.2 Integral transform methodsIf the kernel of an integral equation can be written as a function of the difference
x−zof its two arguments, then it is called adisplacementkernel. An integral
equation having such a kernel, and which also has the integration limits−∞to
∞, may be solved by the use of Fourier transforms (chapter 13).
If we consider the following integral equation with a displacement kernel,y(x)=f(x)+λ∫∞−∞K(x−z)y(z)dz, (23.17)the integral overzclearly takes the form of a convolution (see chapter 13).
Therefore, Fourier-transforming (23.17) and using the convolution theorem, we
obtain
̃y(k)= ̃f(k)+√
2 πλK ̃(k)y ̃(k),which may be rearranged to give
̃y(k)=f ̃(k)
1 −√
2 πλK ̃(k). (23.18)
Taking the inverse Fourier transform, the solution to (23.17) is given by
y(x)=1
√
2 π∫∞−∞̃f(k) exp(ikx)1 −√
2 πλK ̃(k)dk.If we can perform this inverse Fourier transformation then the solution can be
found explicitly; otherwise it must be left in the form of an integral.
Find the Fourier transform of the functiong(x)={
1 if|x|≤a,
0 if|x|>a.Hence find an explicit expression for the solution of the integral equationy(x)=f(x)+λ∫∞
−∞sin(x−z)
x−zy(z)dz. (23.19)Find the solution for the special casef(x)=(sinx)/x.The Fourier transform ofg(x) is given directly by
̃g(k)=1
√
2 π∫a−aexp(−ikx)dx=[
1
√
2 πexp(−ikx)
(−ik)]a−a=
√
2
πsinka
k.
(23.20)
The kernel of the integral equation (23.19) isK(x−z) = [sin(x−z)]/(x−z). Using
(23.20), it is straightforward to show that the Fourier transform of the kernel is
K ̃(k)={√
π/2if|k|≤1,
0if|k|>1.