The Chemistry Maths Book, Second Edition

426 Chapter 15Orthogonal expansions. Fourier analysis

The (trigonometric) Fourier series is usually written in the form

2

(15.37)

and, because of the orthogonality of the expansion functions, the Fourier coefficients

are given by

(15.38)

(15.39)

EXAMPLE 15.5Confirm the relations (i) (15.32) and (ii) (15.35).

(i) By the trigonometric relations (3.22), whenm 1 ≠ 1 n,

so that

and the zero is obtained because the sine of an integer multiple of πis zero.

(ii) Form 1 = 1 n 1 = 10 , whencos 1 mx 1 = 1 cos 1 mx 1 = 11 ,

Z

−

+

−

+

=













=

π

π

π

π

dx x 2 π

=

• 
  

• 
  

• 
  

−

−

















=

−

+

1

2

0

π

π

sin(mnx) sin( )

mn

mnx

mn

ZZ

−

+

−

+

=++−

π

π

π

π

cos cosmx nx dx cos(m n x) cos(m n)

1

2

xxdx













cos cosmx nx=++−cos(m n x) cos(m n x)













1

2

bfxnxdx

n

=

−

+

1

π

π

π

Z ()sin

afxnxdx

n

=

−

+

1

π

π

π

Z ()cos

=+ +

=

∑

a

anxbnx

n

nn

0

1

2

∞

(cos sin)

++ + +bxb xb x

12 3

sin sin 23 sin 

fx

a

( )=+axa xa xcos +cos +cos +

0

12 3

2

23 

2

Jean-Baptiste Joseph Fourier (1768–1830) studied the series in connection with his work on the diffusion of

heat. The work was first presented to the French Academy in 1807, and published in final form in 1822 in the

Théorie analytique de la chaleur(Analytic theory of heat). It generated new developments in the mathematical

theory of functions, and provided a new and powerful tool for the analysis and solution of physical problems.