ZA, 9-11 Nov. 1999
esponding image section
ace is rectified applying a
apped to the corresponding
t of this process is visualized
International Archives of Photogrammetry and Hernote Sensing, Vol. 32, Part 3W14, La Jolla, CA, 9-11 Nov. 1999
Figure 9: Visualization of buildings after texture mapping of
faccades.
5 ALTERNATIVE DATA SOURCES
Up to now airborne laser scanning was applied to provide the
geometric information for building reconstruction, whereas the
image texture was extracted from aerial or terrestrial imagery.
Alternatively, the aerial images can also be applied for height
data acquisition. This would be advantageous since the same
sensor - an airborne camera - can be used to provide the
required geometric and radiometric information. Currently, the
application of aerial images for DSM generation is mainly
hindered by the problems of automatic image matching at
occlusions and height discontinuities, which especially occur in
built-up areas. These problems can be avoided at least to a
certain extend if the applied imagery is captured at a relatively
large scale by a normal angle camera.
Figure 10: DSM from airborne laser scanning
Figure 11: DSM from stereo image matching
An example for the DSM quality, which can be obtained in
urban areas is given in Figure 11 and Figure 10. Figure 10
shows a grayvalue representation of height data acquired by
laser scanning, Figure 11 gives the corresponding result
produced by stereo image matching. In order to generate this
DSM the stereo image pair was captured at an image scale of
1:5000 using a aerial camera with focal length of 305 mm. The
images were scanned with 15 pum resulting in a ground pixel
size of 7.5 cm for each pixel. For DSM generation the standard
software tool MATCH-T was applied (Krystek, 1991). In this
example the results of airborne laser scanning and stereo image
matching can be compared very well since both DSM are
collected with a grid with of 1 m. Whereas for the DSM from
image matching smooth transitions between roof and terrain
surface are visible for some areas, the breaklines are defined
more sharply in the DSM from laser scanning. Additionally,
details like the small tower are only present in the laser DSM.
At the moment the direct height measurement by airborne laser
scanners provides DSM data of higher and more homogeneous
quality especially in urban areas. Nevertheless a lot of effort has
been spent on software development to overcome the
deficiencies of stereo image matching in build-up areas.
Examples are the integration of knowledge on predefined
breaklines or the use of multiple images (Schliiter, 1998). An
additional improvement of the derived DSM data can be
expected by the increasing quality of original stereo image data
if digital aerial cameras are applied (Renouard and Lehmann,
1999). For these reasons, the future development of both
techniques for DSM generation concerning accuracy, reliability
but also cost effectiveness has to be observed carefully.
6 CONCLUSION
Within the paper an approach for the generation of 3D urban
models based on height data from laser scanning and existing
ground plans has been presented. The process enables a fully
automatic reconstruction of the buildings as well as an
interactive refinement of the results provided by the automatic
procedure. This is a main advantage of the presented approach,
since a fully automatic reconstruction is feasible for large areas,
whereas the refinement can be restricted to important parts and
can therefore be performed only on demand. Another advantage
of using a DSM for virtual landscape generation is the good
aptitude of height data for change detection. A change in height
must result from a change in surface geometry, whereas a gray
