International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004
Figure 14: Connected horizontal ridges determine two roof-
units (dark red and bright yellow). Dependent on the size of the
structure (average facet-area) roof-units are eliminated.
Figure 15 shows results for the squaring of roofs. It can be seen,
that additionally triangular facets are eliminated first, so that,
e.g., a hip-roof becomes a more simple saddleback-roof. Like
for the generalization of orthogonal building structures, a
scaling should be added. In this case, it can be restricted to the
z-coordinate. The decision if the original ridge-height, eave-
height, or, e.g, an average of both should be taken for the
result, depends on the goals of the user.
Figure 15: Examples for roof-squaring
3.2 Squaring of wall-structures
The squaring of walls is not realized by now. The basic idea is
that in most cases strong deviations from the right angle have to
he preserved in order to obtain the characteristic shape of a
building (cf. Fig.16, top). Two cases exist, where a wall-
squaring would be reasonable before applying our
generalization process. On one hand, a squaring should be
done, if there are only small deviations from a right angle. This
happens, when the building was not reconstructed from ideal
3D primitives. On the other hand, a structure with strong
deviations, which is small enough to be eliminated in case of
orthogonality (cf. Fig.16, bottom), should be squared, so that
the facets can be merged after a parallel movement.
Figure 16. Strong inclinations have to be preserved for large
structures (top), whereas small parts need to be squared
(bottom)
The squaring of walls is highly non-trivial. While for the
detection of inclined roof-facets reference directions are
available (a roof facet is neither vertical nor horizontal), for
vertical walls the reference directions are the main directions of
the building. These can be seen in nearly all cases as 2D vectors
in the x-y-plane. Yet, even for 2D generalization of ground
plans the derivation of the main orientation is not solved
satisfactory. An overview of common approaches and the
. problems linked with them is given by (Duchéne et al. 2003). In
all of them, a maximum of two main directions is obtained. For
simplification of building data often more than two main
directions would be reasonable (cf. Fig. 17).
R^
Figure 17: Buildings with more than two main directions.
4 CONCLUSIONS AND OUTLOOK
An approach for generalization of 3D building models is
introduced, which is inspired by scale-space theory from image
analysis. Whereas first ideas comprised a combination of
mathematical morphology and curvature space, similar to
reaction-diffusion-space, our new approach allows to simplify
all orthogonal building structures in only one process. It works
by moving parallel facets towards cach other until the facets
meet and merge. Because of this it is suitable only for
orthogonal building structures.
For the therefore necessary squaring of non-orthogonal
structures the treatment of roofs and walls has to be done
differently. A procedure for the squaring of roof-units is
introduced and the main problem concerning the wall squaring
is discussed. The latter is not realized by now. A future goal is
the wall-squaring, particularly the determination of the main
directions of a building. The procedure has to also find the
correspondence between the main directions and building parts.
198
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