ated for
e image
ates the
(Fig. 2),
ympared
e, taken
provides
uce.
on Gra-
) min for
e digital
objects
0 - 2050
ck pixels
rt of the
ons as a
' surface
/hich are
like the
Fig. 8: Comparable image from a distant point of view,
taken with a Rolleiflex 6006 metric,
focal length 250 mm
fence around the platforms on the towers. This objects
are displayed at wrong positions. Problems like this could
only be resolved by refining the DSM.
4. POST PROCESSING
The generation of orthoimages may be carried out with
more than one distorted image. The necessary informa-
tion to fill occluded areas may be extracted from a second
image. But in this case differences in the radiometric
information (brightness, contrast etc.) of the two ortho-
images have to be considered. This may be achieved by
radiometric mosaicking developed for mapping purposes
(Scholten 1996).
An additional post processing technique may be the geo-
metric comparison of two orthoimages, interactively or
automatically by matching techniques. If the images have
been exposed at the same day, local geometric diffe-
rences of the two orthoimages can be explained as errors
in the DSM. If the two images are from different exposure
dates the differences may be the results of changes of
609
the object. This approach could be used for automatic
damage analysis.
5. CONCLUSION
At present the generation of the CAD model is the most
tedious task in the production of orthoimages. New de-
velopments, such as semi-automatic or automatic digital
restitution techniques, will accelerate this process and
provide the necessary data fast and cheap (Streilein
1994). New users of orthoimages can be anticipated in the
world of computer graphics. Orthoimages are well suited
for texture mapping in Virtual Reality Models.
Architectural photogrammetric data may be used for the
documentation of historical sites and monuments, for the
determination of damages, or for civil and building engi-
neering purposes. The requirements for such data are
undisputed (Waldháusel 1992) and permanently con-
firmed by the news about destroyed buildings we see
every day on TV.
The rectification of architectural imagery has a very long
tradition. But thanks to the digital image processing also a
successful future, and new users can be anticipated.
REFERENCES
Li, R., 1993. Generation of geometric representations of
3D objects in CAD/CAM by digital photogrammetry. ISPRS
Journal of Photogrammetry and Remote Sensing, 48(5):
pp. 2-11.
Marten, W., L. Mauelshagen & R. Pallaske 1994. Digital
orthoimage-system for architecture representation.
ISPRS Journal of Photogrammetry and Remote Sensing,
49(5): pp. 16-22.
Mayr, W. & Ch. Heipke 1988. A Contribution to Digital
Orthophoto Generation. In: International Archives of
Photogrammetry and Remote Sensing, Kyoto, Japan, Vol.
XXVII, Part. B11, pp. 430-439.
Scholten, F., 1996. Automated Generation of Coloured
Orthoimages and Image Mosaics Using HRSC and
WAOSS Data of the Mars 96 Mission. In: International
Archives of Photogrammetry and Remote Sensing, Wien,
Austria, Vol. XXXI, Part. B3.
Streilein, A., 1994. Towards automation in architectural
photogrammetry: CAD-based 3D-feature extraction.
ISPRS Journal of Photogrammetry and Remote Sensing,
49(5): pp. 4-15.
Waldhäusl, P., 1992. Defining the future of Architectural
Photogrammetry. In: International Archives of Photo-
grammetry and Remote Sensing, Washington, USA, Vol.
XXIX, Part. B5, pp. 767-770.
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B5. Vienna 1996
