1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

110 Chapter 1 Fourier Series and Integrals

Sincef(x)=0 forx>π, the integral forB(λ)reduces to one over the interval
0 <x<π:

B(λ)=

2

π

∫∞

0

f(x)sin(λx)dx=

2

π

∫∞

0

sin(x)sin(λx)dx

=

2

π

[sin((λ− 1 )x)

2 (λ− 1 ) −

sin((λ+ 1 )x)

2 (λ+ 1 )

]π

0

=^2

π

[

sin((λ− 1 )π )

2 (λ− 1 )

−sin((λ+^1 )π )

2 (λ+ 1 )

]

.

This expression can be simplified by using the fact that

sin

(

(λ± 1 )π

)

=sin(λπ±π)=−sin(λπ ).

Then, creating a common denominator, we obtain

B(λ)=−π(λ2sin (^2) −(λπ ) 1 ).
Hence the Fourier sine integral representation off(x)is
f(x)=

∫∞

0

−2sin(λπ )

π(λ^2 − 1 )

sin(λx)dλ, 0 <x.

Sincef(x)is continuous for 0<x, the equality holds at every point.
Similarly, we can compute the cosine coefficient function

A(λ)=−^2 (^1 +cos(λπ ))

π(λ^2 − 1 )

,

and the cosine integral representation off(x)is

f(x)=

∫∞

0

− 2 ( 1 +cos(λπ ))

π(λ^2 − 1 ) cos(λx)dλ,^0 <x.

Note that bothA(λ)andB(λ)have removable discontinuities atλ=1.

It seems to be a rule of thumb that if the Fourier coefficient functionsA(λ)
andB(λ)can be found in closed form for some functionf(x), then the inte-
gral in the Fourier integral representation cannot be carried out by elementary
means, and vice versa. (See Exercise 3.)
Rules for operations on Fourier integrals generally follow the lines men-
tioned in Section 1.5 for Fourier series. In particular: Iff(x)is continuous and
if bothf(x)andf′(x)have Fourier integral representations, then

f(x)=

∫∞

0

[

A(λ)cos(λx)+B(λ)sin(λx)

]

dλ,