functional form independent of its position (shift invariant) then the
equation (2-2) can he expressed as equation (2-1).
f | h | g
Fig 2.1 A Linear System.
2.3 The Fourier Transform
A one-dimensional £orward Fourier transform of a function g(x) is
defined by
+ ©
Gta) = Fégla3) = flats) 0727305 dx
©
where j 2Y-1 . The operator F defines the Fourier operation. The
inverse Fourier transform is defined by
+
qa) = FÎ(GCa)) = J'Ets) e* DM dB
The power spectrum of a function g(x) is defined as
p(s) = abs(F(g(x))?
which is a description of the distribution of the energy of the
function at certain frequencies. The convolution in the spatial domain
corresponds to multiplication in the frequency domain (and vice versa).
This means that
F(g(x)*h(x)) G(s)H(s)
and
F(G(s)*H(S))
i
g(x)h(x)
which in linear system analysis is called the convolution theorem,
3. MODELLING
3.1 Image Models
There are several models for describing a digital image (Rosenfeld,
1981). Two common models will be described here: statistical and
deterministic (Andrews and Hunt, 1977).
3.1.1 Statistical Image Model
In a statistical model of an image we assume that each component
(pixel) in the image results from a random variable. Thus, each image
is the result of à family of random variables, a random field. A
random field is a two-dimensional case of a random process. Consider
the random field f(r,w,) where r is a vector in the xy-plane. For à
given outcome Wj, f(r,wj) isa function over the xy-plane. A sequence
of such functions is an ensemble. For a given value of r, f(ür,w;) isa
random variable. The expectation of this random variable mg(r) -
Et£(r)) is an ensemble average and is called the mean of the random
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