is sought. More specifically, a bound on sub-pixel pointing precision will
be derived based on a simple image parameter.
Resolution and precision are different but related concepts in digital
imagery just as they are in photography. Resolution is associated with
recognizability, while precision is associated with locatability.
Resolution is related to the ability to distinguish two closely spaced
objects, while precision is related to the error in estimating the distance’
between two (resolvable) objects. Recognizable objects within an image are
referred to as "detail", thus we will be exploring precision of estimates of
the geometric position of image detail.
The geometric precision which is obtainable from a digital image may be
restricted by a number of factors. The pixel size, scanning pattern,
aperture shape and size, dynamic range, and character of image detail will
all affect the precision. Knowledge of the available precision may be
useful in many ways: The design of control points to be included in
digital imagery, and the selection of properties of the image scanning
equipment may be directed by their effect on the geometric precision in the
resultant image; image 'correlation' procedures might use a measure of the
available precision to dynamically set parameters of the algorithm; various
algorithms may be compared on the basis of how close they come to a known
upper bound on precision and the trade-offs among parameters such as
aperture size, dynamic range, and sampling interval may be evaluated.
The contents of the image plays.an important role in determining the
available geometric precision. To illustrate this point, consider the case
of two long straight parallel railway tracks. If the two tracks are
resolvable, however well, then by performing a simple fitting algorithm a
very good estimate can be made of the gauge of the railway. In contrast,
any estimate for the length of one railway tie (considered in isolation)
will be much less precise.
This dependence on image content makes it unlikely that geometric precision
can be clearly defined independent of application. The use of standard
targets such as bar charts has been the time honoured basis of resolution
measurements. À similar approach may be in order for general precision
measurements in digital imagery but, for specific applications where
objects of known shape are to be located, a more detailed analysis may be
necessary.
nted in section 2 for image det
8 inten tion 1 o establish a methodology and
ecision Rin digital imagery may be analysed ri ously.
The model divides a pixel in regions, each of which is refered to as a
'locale'. The number of locales ae a pixel provides a bound on their
size, which in turn will bound the av able geometric precision. The
development of the formal model is pre ced with an heuristic discussion, and
followed by some illustrative example
A formal mathematical
absence of noise. Th
by which geometric pr
model is pre il in the
am
ta
framework
or
cg
5
Oo
o m
or
Based on the formal model, a bound is established in section 3 for the number
of locales, and the implications to data storage are discussed in section 4.
In section 5 a bound is established for geometric precision with noise in the
image. The space-optimal configuration of scanner sampling interval and
f ts per pixel is discussed.
