it
reduction of non-measurement error sources should
be investigated.
8. Conclusions
This study shows that digital image processing can
improve both the precision and the productivity of
the close-range photogrammetry. In order to
optimize these two aspects it is necessary to
improve some parts of the digital photogrammetric
process.
Looking at productivity the time needed for
digitilisation (6 hours per negative) should be
reduced. À new version of the ASTROSCAN is
being developed needing about half the time. If the
need for faster digitalization arises using another
digitizer should be considered. A CCD-camera is
an alternative for obtaining the digital images. Then
the problem of film deformation and therewith the
need for reseaucrosses and their matching would be
eliminated.
The computational burden of the matching process
is a second productivity aspect. The 4 hours per
negative needed in the experiment (for an average
negative: 121 reseaucrosses and 50 targets) using a
80386 processor based PC. This can be reduced
through optimization of the software and by
utilizing a faster computer. However, these time
apects have only importance if results are needed
within a short timescale. It should be noted that
digitizer and computer can operate 24 hours a day
without manual interaction.
As far as precision is concerned, the experiment
showed an improvement of a factor 1.4 in variance.
Further improvement is expected from a better film
deformation model; also reduction of the film
deformation itself should be aimed at. A second
aspect influencing the precision is the camera
model. Especially for a camera with a relatively
short focal length (40 mm for the camera used in
the experiment) an extension of the model with a
few degrees of freedom is to be investigated.
229
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