1540470959-Boundary_Value_Problems_and_Partial_Differential_Equations__Powers

122 Chapter 1 Fourier Series and Integrals

=^1

2 

∑∞

−∞

f

(nπ



)

exp

(−inπω



)

, −<ω<.

By utilizing Eq. (1) again, we can reconstructf(t):

f(t)=

∫

−

C(ω)exp(iωt)dω

=^1

2 

∑∞

−∞

f

(

nπ



)∫

−

exp

(

−inπω



)

exp(iωt)dω.

Carrying out the integration and using the identity

sin(θ )=(e

iθ−e−iθ)

2 i ,

we find

f(t)=

∑∞

−∞

f

(

nπ



)sin(t−nπ)

t−nπ. (3)

This is the main result of the sampling theorem. It says that the band-limited
functionf(t)may be reconstructed from the samples offatt=0,±π/,....
It is difficult to determine what functions are actually band limited. However,
the process usually works quite well.
In practice, we must use a finite series to approximate the function

f(t)∼=

∑N

−N

f

(nπ



)sin(t−nπ)

t−nπ

. (4)

Since the sampled values all come from the interval−Nπ/toNπ/,the
series cannot attempt to approximate the function outside that interval. An
animation on the CD shows the effects of choosingNand.

Example.
The function

f(t)= t

(^2) + 2 t
( 1 +t^2 )^2
is not band limited but can be approximated satisfactorily from a finite por-
tion of the sum as in Eq. (4). Figure 13 shows results forN=100 (that
is, 201 terms) and=4 and 10. The target function is dashed. Notice the
improvement.