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support the operator during the orientation process are still
under development.
2.5 Differential Rectification
The DSM and the oriented image data are combined and digital
orthoimages are created in a short period of time. We used a
digital consumer camera (Nikon Coolpix 4300). Because of the
significant distortion of the optics, it was necessary to consider
them in the orientation and rectification. The distortion model
described in Luhmann (2000) has been used.
Figure 4. Orthoimage
If the results are insufficient, for example because of
inaccessibility of some parts of the object, there are techniques
to solve any ambiguities by using digital photogrammetry based
Figure 5: Drawings derived from the Orthoimages and some
additional geodetic information.
on the acquired and oriented images at any time after the
campaign.
In the result the balconies are located at the correct location.
Above them are some occluded areas, which have been colored
in gray in the orthoimage. If additional image from a better
point of view are available this gaps in the orthoimages can be
closed during the mosaiking process. The roof has been
removed. The image of the roof is not suited for this purpose,
because of the inappropriate aspect.
3. DRAWINGS
Based on this orthoimages line drawings of the object have been
derived. This has been performed by monoplotting on the
orthoimage. A small part is shown n Fig. 5. The heights of the
roof and the chimneys have been added based on geodetic
measurements.
4. MOSAIKING
Digital orthoimages or rectified images can be combined to
mosaics. The example for this is a parametric rectification of
three digital images (Fig. 6). The exposure time was selected
automatically, so that the images show very different brightness
and contrast. After a parametric rectification (Fig. 7), using
Archimedes3D Basic the three rectified images are mosaiked
geometrically (Fig. 8). The differences in brightness and
contrast are clearly visible. To avoid this a radiometric
mosaiking tool, based on the approaches for satellite image data
(Kahler 1989) has been adapted for architectural images. The
concept is an equalisation of the sum histograms. The result of
this fully automatic process is shown in figure 9.
5. CONCLUSIONS
Using this package, a total station and a digital camera become
a high quality documentation system providing detailed data for
the generation of real orthoimages and other requested products
in heritage documentation.
6. REFERENCES
Juretzko, M., 2002: The System TOTAL for Recording the
Geometry and Image Data of Historic Buildings and
Monuments. Proc. of the XVIII. CIPA Int. Symposium,
Potsdam, Germany, Oct. 18.-21 2001. International Archives
for Photogrammetry and Remote Sensing (IAPRS). Vol.
XXXIV-5/C7, pp. 611-613.
Kahler, M., 1989: Radiometrischen Bildverarbeitung bei der
Herstellung von Satelliten-Bildkarten. Deutsche Geoatische
Kommision DGK, Reihe C 348.
Luhmann, T., 2000: Nahbereichsphotogrammetrie. Wichmann,
Karlsruhe.
Wehr, Aloys & Albert Wiedemann (1999): Fusion of Photo-
grammetric and Laser Scanner Data Proc. of the CIPA Int.
Symposium '99, Int. Archives for Photogrammetry and Remote
Sensing, Vol. XXXIV, Part 5C1B, Olinda, Brazil, 3.-6. Okt.
1999, published on CD & on http://www.fpk.tu-
berlin.de/~albert/litlis.html
Wiedemann, A. (1996): Generation of Digital Orthoimages
Using Digital Surface Models. International Archives for
