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FACADE DETAIL FROM INCOMPLETE RANGE DATA
Jan Böhm
Institute for Photogrammetry, Universität Stuttgart, Germany
jan.boehm@ifp.uni-stuttgart.de
Commission V, WG V/4
KEY WORDS: Range Data, LIDAR, Building, Façade, Modelling, Matching
ABSTRACT:
In recent years, the demand for highly detailed building models has clearly risen. Most of the details, which characterize a building,
come from its façade. It is obvious that such façade detail is ideally acquired from ground-based sensors. For any street-level data
acquisition system, a common problem arises: that of occlusions and hence incomplete data. In the past we have shown how multi
image coverage can overcome occlusions in image based façade recording. In this paper, we demonstrate new approaches on façade
detail from range data in the case of incomplete data. The approach builds on our development of LASERMAPs, a simple and
efficient way to use street-level LiDAR data to enhance existing prismatic building models.
1. INTRODUCTION
The impressive advances in the automatic generation of virtual
city models achieved within the photogrammetric community in
recent years, have contributed to the widespread dissemination
of such models to various end-user platforms. So called ‘digital
globes’ have become an especially popular platform for LODI
(level-of-detail 1) models, which feature simple block models
without roof structures. Lately L0D2 models have been
released, which feature detailed roof structures, while the body
remains a simple prism enriched by colour texture. See (Kolbe
& Grôger, 2003) for a detailed definition of the LOD hierarchy.
However, the use of highly sophisticated computer equipment
and enormous manpower in the modem media and
entertainment industry, which can be experienced in stunning
computer graphics special effects in movies or highly detailed
three-dimensional video games, has further raised the
expectations of today’s audiences to the quality of computer
generated content and visualizations techniques. These
expectations can not be fully met by today’s city models.
Furthermore the dominant business concept behind digital
globes, the advertisement market, requires the spectacular and
recognizable presentation of local businesses within the models.
It is therefore foreseeable, that the level of detail has to be
further increased and the time for widespread dissemination of
LOD3 models is near. Increased detail can only come from
three-dimensional façade detail, which in turn can only be
achieved by ground-based sensors. An overview of how to
create detailed 3D models for buildings in cities from terrestrial
data is given in (Mayer et al., 2008).
We have developed an approach which efficiently combines the
coarse geometry of an existing LOD2 building model with the
detailed features form ground-based LiDAR data which is based
on our concept of LASERMAPs. In the case of a LOD2
building model, the approach is straight forward, since the
coarse geometry is described by a polyhedral boundary
representation and facades are typically planar polygons. This
property is also exploited when intensity images are used for
texture mapping. In order to use a similar 2D-2D mapping for
the integration of terrestrial LiDAR data, we have to derive a
two-dimensional representation of the point cloud. Obviously,
this is not possible for the whole point cloud. We rather have to
split the point cloud into groups with respect to the facades of
the building using a simple buffer operation for each facade
polygon. The portion of the point cloud that belongs to a
particular facade can then be interpolated into a regular raster,
in a fashion very similar to digital elevation models derived
from aerial LiDAR.
In ground-based façade scanning, as in any ground-based data
acquisition, incomplete data acquisition is a major problem and
a primary reason for insufficient data quality. Incomplete data
acquisition can occur for multiple reasons. One cause is the
partial occlusion of the façade by other objects, such as cars,
trees, pedestrians, street signs and so on. Figure 1 shows an
extreme case for an occlusion by a tree and the incomplete data
it causes. Another cause is the self occlusion of the façade due
to an oblique viewing angle. Protruded balconies or indented
windows will cast shadows along the direction of measurement
and cause incomplete data acquisitions. While such effect can
be minimized by proper station planning, we have to keep in
Figure 1. Incomplete ground-based LiDAR data due to an
occlusion by a tree. The example is taken from a dataset
shown figure 2Figure 2.
