The greatest difference in the values of so and 5, oc-
curs, if different numbers of pictures are used for surface
reconstruction with FAST Vision. The values are the
lower, the more pictures are used. Fig. 5.1 shows sy for
all stripes and all numbers of pictures for regulariza-
tion by curvature minimization and A=2000. Fig. 5.2
shows 5 for the same case.
The number of iterations using adaptive regularization is
almost always higher than that using regularization by
curvature minimization. This effect results from the hig-
her degree of freedom of adaptive regularization.
A comparison of the heights resulting from automatic
surface reconstruction with FAST Vision and the values
measured by a human operator will be carried out in
the near future.
standard deviation
of unit weight
“lo [] 2 pictures
3 pictures
4 pictures
{
stripe 1
1
stripe 2
I i
stripe 3 stripe 4 /
Fig. 5.1: Standard deviation of unit weight dependent on
number of pictures used for FAST Vision
mean standard deviation
of heights (metres)
0,05
1 2 pictures
3 pictures
2 4 pictures
Fig. 5.2: Mean standard deviation of heights dependent
on number of pictures used for FAST Vision
0,00 w* I I Ï I
stripe 1 stripe 2 stipe 3 stripe 4
6. Conclusions
Two aspects were important in the experiments carried
out in this paper: How will the results of the recon-
struction of different surfaces differ, if both methods of
regularization, regularization by curvature minimization
or by adaptive regularization, are used? And will there
be a noticable improvement in the reconstruction of
surfaces, if the input data consists of more than two
pictures?
The answer to the latter question is clearly positive. The
addition of a third picture not only lowers the values of
standard deviation of unit weight and the mean stan-
dard deviations of heights, but also cuts down the
number of iterations necessary to meet the break-off
criterion. Using four instead of three pictures does not
result in such a big improvement, but one has to keep
in mind, that one of three pictures or its orientation data
might be of poorer quality. Then, the addition of a
fourth picture would increase the reliability of the
recontruction results.
816
The comparison of the two regularization methods de-
pends on several prameters. Surfaces containing edges
are better reconstructed using adaptive regularization,
whereas the assumption of smoothness implied in regu-
larization by curvature minimization yields better re-
construction of smooth surfaces as long as the regulari-
zation parameter À is chosen not too high. Surface 1
(rfpar) and 2 (rfrot) are composed of Z-facets with
zero curvature almost everywhere. On surfaces 3 (cyl.
par.) and 4 (cylrot) one of the principal curvatures is
zero everywhere and the other varies from almost zero
to low values only. So, there are good conditions for
applying regularization by curvature minimization. The
secorid method - adaptive regularization - is practically
independent of the type of surface curvatures, but as it
offers much more degrees of freedom to the object sur-
face model the results show up more roughness than
with the first method. Adaptive regularization was
introduced in order to yield recontruction results not so
dependent on that choice of A, this property is confir-
med by the experiments: The reconstruction results deri-
ved from regularization by curvature minimization get
worse with increasing A in general, which is not true if
adaptive regularization is used. The price to be paid for
using adaptive regularization is a higher number of
iterations.
T. References
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Weisensee, M.: Modelle und Algorithmen für das Facet-
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Wrobel, B.: Digital Image Matching by Facets Using Ob-
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um on Optical and Optoelectr. Appl. Science
and Engineering, March 30th-April 3rd 1987,
The Hague, Netherlands, SPIE 804, p.p.
325-333
Wrobel, B.: The Evolution Of Digital Photogrammetry
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1991 R
Wrobel, B./ Kaiser, B./ Hausladen, ]: Adaptive Regulari-
zation of Surface Reconstruction By Image
Inversion. In: Fórstner, W./ Ruwiedel, St. (eds) :
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Wrobel, B./ Kaiser, B./ Hausladen, J.: Adaptive Regulari-
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These investigations are supported by Deutsche
Forschungsgemeinschaft.
