1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

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1.11 Applications of Fourier Series and Integrals 119


Next, suppose thatr(t)is a square-wave function with Fourier series


r(t)=

∑∞

n= 1

2 ( 1 −cos(nπ))
nπ sin(nt).

The corresponding response is


y(t)=

∑∞

n= 1

2 ( 1 −cos(nπ))
nπ ·

− 0. 4 ncos(nt)+( 1. 04 −n^2 )sin(nt)
( 1. 04 −n^2 )^2 +( 0. 4 n)^2.

Note that the term forn=1 has a small denominator, causing a large
response. 


B. Boundary Value Problems


By way of introduction to the next chapter, we apply the idea of Fourier series
to the solution of the boundary value problem


d^2 u
dx^2 +pu=f(x),^0 <x<a,
u( 0 )= 0 , u(a)= 0.

First, we will assume thatf(x)is equal to its Fourier sine series,


f(x)=

∑∞

n= 1

bnsin

(nπx
a

)

, 0 <x<a.

And second, we will assume that the solutionu(x), which we are seeking,
equals its Fourier sine series,


u(x)=

∑∞

n= 1

Bnsin

(

nπx
a

)

, 0 <x<a,

and that this series may be differentiated twice to give


d^2 u
dx^2 =

∑∞

n= 1


(n (^2) π 2
a^2 Bn


)

sin

(nπx
a

)

, 0 <x<a.

When we insert the series forms foru,u′′,andf(x)into the differential
equation, we find that


∑∞
n= 1

(

−n

(^2) π 2
a^2
Bn+pBn


)

sin

(

nπx
a

)

=

∑∞

n= 1

bnsin

(

nπx
a

)

, 0 <x<a.
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