Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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12.7 COMPLEX FOURIER SERIES


where the Fourier coefficients are given by


cr=

1
L

∫x 0 +L

x 0

f(x)exp

(

2 πirx
L

)
dx. (12.10)

This relation can be derived, in a similar manner to that of section 12.2, by mul-


tiplying (12.9) by exp(− 2 πipx/L) before integrating and using the orthogonality


relation


∫x 0 +L

x 0

exp

(

2 πipx
L

)
exp

(
2 πirx
L

)
dx=

{
L forr=p,

0forr=p.

The complex Fourier coefficients in (12.9) have the following relations to the real


Fourier coefficients:


cr=^12 (ar−ibr),

c−r=^12 (ar+ibr).

(12.11)

Note that iff(x)isrealthenc−r=c∗r, where the asterisk represents complex


conjugation.


Find a complex Fourier series forf(x)=xin the range− 2 <x< 2.

Using (12.10), forr=0,


cr=

1


4


∫ 2


− 2

xexp

(



πirx
2

)


dx

=


[



x
2 πir

exp

(



πirx
2

)] 2


− 2

+


∫ 2


− 2

1


2 πir

exp

(



πirx
2

)


dx

=−


1


πir

[exp(−πir)+exp(πir)]+

[


1


r^2 π^2

exp

(



πirx
2

)] 2


− 2

=

2 i
πr

cosπr−

2 i
r^2 π^2

sinπr=

2 i
πr

(−1)r. (12.12)

Forr= 0, we findc 0 = 0 and hence


x=

∑∞


r=r=0−∞

2 i(−1)r

exp

(


πirx
2

)


.


We note that the Fourier series derived forxin section 12.6 givesar=0forallrand


br=−

4(−1)r
πr

,


and so, using (12.11), we confirm thatcrandc−rhave the forms derived above. It is also
apparent that the relationshipc∗r=c−rholds, as we expect sincef(x)isreal.

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