Mathematical Methods for Physics and Engineering : A Comprehensive Guide

FOURIER SERIES

apply forr= 0 as well asr>0. The relations (12.5) and (12.6) may be derived

as follows.

Suppose the Fourier series expansion off(x) can be written as in (12.4),

f(x)=

a 0

2

+

∑∞

r=1

[

arcos

(

2 πrx

L

)

+brsin

(

2 πrx

L

)]

.

Then, multiplying by cos(2πpx/L), integrating over one full period inxand

changing the order of the summation and integration, we get

∫x 0 +L

x 0

f(x)cos

(

2 πpx

L

)

dx=

a 0

2

∫x 0 +L

x 0

cos

(

2 πpx

L

)

dx

+

∑∞

r=1

ar

∫x 0 +L

x 0

cos

(

2 πrx

L

)

cos

(

2 πpx

L

)

dx

+

∑∞

r=1

br

∫x 0 +L

x 0

sin

(

2 πrx

L

)

cos

(

2 πpx

L

)

dx.

(12.7)

We can now find the Fourier coefficients by considering (12.7) asptakes different

values. Using the orthogonality conditions (12.1)–(12.3) of the previous section,

we find that whenp= 0 (12.7) becomes

∫x 0 +L

x 0

f(x)dx=

a 0

2

L.

Whenp= 0 the only non-vanishing term on the RHS of (12.7) occurs when

r=p,andso

∫x 0 +L

x 0

f(x)cos

(

2 πrx

L

)

dx=

ar

2

L.

The other Fourier coefficientsbrmay be found by repeating the above process

but multiplying by sin(2πpx/L) instead of cos(2πpx/L) (see exercise 12.2).

Express the square-wave function illustrated in figure 12.2 as a Fourier series.

Physically this might represent the input to an electrical circuit that switches between a
high and a low state with time periodT. The square wave may be represented by

f(t)=

{

−1for−^12 T≤t< 0 ,

+1 for 0≤t<^12 T.

In deriving the Fourier coefficients, we note firstly that the function is an odd function
and so the series will contain only sine terms (this simplification is discussed further in the