a linear shift invariant operator h(x) , which, together with an
additive noise term n(x), operates on an input image (or signal) f(x)
to produce à degraded output image g(x):XFig.3.0. This may be ex-
pressed as
gi): m hot) 4 n(x) (3-1)
The operator h is commonly referred to as the point-spread-function
(ps£) of the process. This function, however, is for many imaging
systems, a product of several psf components, where each component is
assumed to correspond to a linear shift invariant system. Such
components can be caused by for example diffraction, abberation,
defocusing, motion blur and atmospheric turbulence (Castleman, 1979).
The noise term n(x) is assumed to be à random variable. Images
orginally recorded on photographic film are subject to degradation due
to film grain noise. In addition to this, the digitizing or sampling
process generates noise due to quantization, sampling rate and signal
variation. In equation (3-1) the noise is assumed to be signal in-
dependent. Unfortunately, in reality this is seldom the case. Much
of the noise in the process is signal dependent, film grain noise for
example (Andrews and Hunt 1979, Sondhi 1972, Pratt 1978). However, to
simplify the description the independent model for the noise will be
used,
3.3 Determination of Degradation Parameters
The aim of image restoration is to estimate the original image f hy
using the recorded image g and knowledge concerning the degradation
process. Such estimation, however, requires some form of knowledge
concerning the degradation function h. An example of a priori de-
termination is an experiment by McGlamery (1967) where determination of
the turbulence psf was made. A posteriori determination of the psf may
be performed by measuring the density of a sharp point in the degraded
image. It is then assumed that the point in the original image is an
approximation of the impulse function (Fig 3.2). In the same way the
psf may be determined a posteriori from lines and edges (Andrews and
Hunt 1977, Rosen£eld and Kak 1976, Pratt 1978). In the presence of
noise it is also desirable to have some knowledge about the statistical
properties of the noise. The noise is usually assumed to be white i.e.
the expectation of the power spectrum of the noise iS constant. This
assumption is convenient but somewhat inaccurate (Rosenfeld
Fig 3.2 Determination of the
psf. The original sharp point
to the right is deblurred by
the psf (left image).
and Kak, 1976). Different restoration techniques require different
amounts of a priori information about noise. Wiener filtering requires
knowledge about the noise power spectrum. In constrained restoration,
however, knowledge of the variance of the noise is nesessary.
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