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Moving the sample locations to achieve the desired warping will result in an
irregularly sampled image plane. These irregularly spaced samples will then be
brought back to regularly spaced positions, hence warping the image. Typical
restoration techniques can then be performed using these regularly spaced
samples. A method of optimally finding these sample positions is given below.
Only the one-dimensional case will be considered here; the two-dimensional case
will be attempted in the future.
The linear mapping of Eq. 1 is put into discrete form, with
uniformly spaced samples of 
and
. In one dimension, Eq. 1 then
becomes
where uniform sampling, 
and 
,
is often assumed. The sampled impulse response, 
, is a function of
the 
sample positions, 
. In particular,
describes the amount the 
object sample affects
the image 
samples away from the 
image sample.
The sample locations are to be moved so that the resulting impulse response
is approximately space-invariant. To this end, the invariant term of
Eq. 3 can be found, in sampled form for a one dimensional
mapping, to be
Since 
and 
are not predetermined, their explicit dependence on
is unnecessary. Let 
and 
. A space-invariant impulse response should not depend on the
coordinate of the object, i.e., a space-invariant impulse response should obey
, 
. If this equality does
not hold, then the difference between the different impulse responses describes
an error from the assumption of shift-invariance.
A metric which measures the total error over the field is
where the limits of the image are 
. The limits on the
summations keep the sample points within the image boundaries. Allowing the
sum to go outside the image boundaries (
or 
) includes
some ``anchor'' samples outside the image, which tends to stabilize the
solution trajectory when 
is minimized. For example, if all of the sample
positions may be moved, there is a global minimum (
) when all of the
samples are co-located. If all of the sample positions which start off inside
the image are forced to remain in the image, then keeping a fixed sample
position outside the image removes this zero point. Note also that
describes the distance from the ``center'' of the space-variant impulse
response. The limits on could therefore be constrained PSFs with support
more compact than that of the entire image (which is usually the case).
However, it is the actual distance 
, not just the magnitude of
, which needs to be within the support of the PSF. Since the solution will
necessarily change the sample locations, the limits on will depend upon
the resulting sample locations.
The goal here is to minimize . This will provide a sampling scheme which
will yield the most space-invariant impulse response.
For minimization, the gradient elements 
are needed.
An application of the chain rule gives
When expressed in the form of Eq. 6, the value inside the
summations of are symmetric with respect to 
and 
, so there are
redundant terms when forming the product in the summations of .
Accounting for these redundant terms with a scaling factor of two, and
rearranging,
The lower (
) term sifts through the sum in a straightforward
manner. The upper (
) term can sift through either or .
Since
the sum will be sifted in the lower equation, and will typically have more
terms than the sum (making sifting through computationally beneficial),
the sum will be sifted through the upper term as well.
The sifting for the 
term is still not straightforward, since
the limits on are a function of . The bookkeeping is as follows:
- The limits on are
,
and at 
this range is at its maximum: 
.
For any , the limits of fall within this range.
- For
, the possible values of run over
.
- The net permissible range of is that range for which both of the
above conditions hold, i.e., the intersection of the above ranges.
With these new limits on , the substitution 
completes the sifting
process of 
. If compact support of 
is also included
(
), then the permissible values of are
The gradient elements then become
The minimization used is a version of the steepest descent technique for
finding zeros of functions. Each sample position is incremented by
(
),
where
and 
is the iteration counter. This expression describes the shortest
Euclidean line between the current point, , and the
plane, along the hyperplane which is tangent to . This
technique was used because of its simplicity - errors in the software were
easily tracked because each step could be followed. This method is designed to
find zeros, not minima, so it was adapted by decreasing the size (but
maintaining the direction) of sample position jumps which would create an
larger than that of the previous iteration. When minima were reached, the
magnitude of the sample position jumps got cut drastically (
). If this was suspected to be a local minima then a
large increment was permitted, effectively searching a new solution space
(similar to simulated annealing).
Another constraint added to this procedure was that sample points were not to
cross over one another (Let 
be an increasing
sequence. 
then must be an increasing sequence
). If any pair of sample locations approached each other too fast
in any given iteration step (e.g., if 
then 
or
, as appropriate, was decreased so that 
.
Next: Results
Up: Approximate Shift-Invariance by Warping
Previous: Introduction