1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

1.8 Numerical Determination of Fourier Coefficients 103

Ifris odd, Eqs. (3) and (4) are valid forn= 1 , 2 ,...,(r− 1 )/2, giving a total of
rcoefficients. Ifris even, Eq. (4) givesbˆr/ 2 =0, and Eq. (3) has to be modified:

aˆr/ 2 =^1

r

(

f(x 1 )cos

(rπx

1

2 a

)

+···+f(xr)cos

(rπx

r

2 a

))

. (3′)

We again getrvalid coefficients.

The formulas in Eqs. (2)–(4) were derived for the case in whichx 0 ,x 1 ,...,xr
are equally spaced points in the interval−a≤x≤a. However, they remain
valid for equally spaced points on the interval 0≤x≤ 2 a.Thatis,

x 0 = 0 , x 1 =

2 a

r, x^2 =

4 a
r, ..., xr=^2 a. (5)
Note also that whenf(x)is given in the interval 0≤x≤aand the sine or co-
sine coefficients are to be determined, the formulas may be derived from those
already given here. Let the interval be divided intosequal subintervals with
endpoints 0=x 0 ,x 1 ,...,xs=a(in general,xi=ia/s). Then the approximate
Fourier cosine coefficients forfor its even extension are

aˆ 0 =

1

s

( 1

2 f(x^0 )+f(x^1 )+···+f(xs−^1 )+

1

2 f(xs)

)

,

aˆn=

2

s

( 1

2 f(x^0 )+f(x^1 )cos

(nπx

1

a

)

+···+

1

2 f(xs)cos

(nπx

s

a

))

,

n= 1 ,...,s− 1 ,

aˆs=

1

s

( 1

2 f(x^0 )+f(x^1 )cos

(sπx

1

a

)

+···+

1

2 f(xs)cos

(sπx

s

a

))

. (6)

Similarly, the approximate Fourier sine coefficients forfor its odd extension
are

bˆn=^2

s

(

f(x 1 )sin

(nπx

1

a

)

+···+f(xs− 1 )sin

(nπx

s− 1

a

))

,

n= 1 , 2 ,...,s. (7)

An important feature of the approximate Fourier coefficients is this: If

F(x)=ˆa 0 +ˆa 1 cos

(πx

a

)

+ˆb 1 sin

(πx

a

)

+···

is a finite Fourier series using a total ofrapproximate coefficients calculated
from Eqs. (3) and (4), thenF(x)actuallyinterpolatesthe functionf(x)at
x 1 ,x 2 ,...,xr.Thatis,

F(xi)=f(xi), i= 1 , 2 ,...,r.