International Archives of Photogrammetry and Remote Sensing, Vol. 32, Part 7-4-3 W6, Valladolid, Spain, 3-4 June, 1999
Another possibility to improve object detection based on DSM
resulting from airborne laser scanning is the further analysis of
the reflected laser beam. Laser scanning systems can be
separated into continuous wave or pulsed laser systems. If a
pulsed laser system is applied, multiple reflections will occur
during the acquisition of trees. As depicted in Figure 2, during
measurement of trees a certain percentage of the laser footprint
will be reflected by the branches and leaves of the tree. Other
parts will penetrate the foliage and will be finally reflected by
the terrain surface. For this reason the top of the tree refers to
the first echo of the laser pulse, which is recorded by the laser
sensor, while the last echo usually refers to the terrain surface.
first response
reflections at
foliage
last response
reflection at
terrain
Fig. 2. Reflection of a laser pulse at trees.
Fig. 3. Grey value representation of DSM derived from first
echo measurement.
If the laser system is capable of recording and discriminating
multiple laser pulse echoes, they can be utilized in order to
separate trees and buildings. Figure 3 shows a grey value
representation of a normalized laser DSM. The original DSM,
which was already depicted as 3D visualization in Figure 1, is
based on the first echo measurement. For this reason, both trees
and buildings are visible. Figure 4 shows the corresponding
result for a DSM derived from last echo measurements. In this
example, only the buildings are visible. Hence, the difference
between first and last echo normalized DSMs can be used for
the detection of tree regions.
Fig. 4. Grey value representation of DSM derived from last
echo measurement.
The laser system we are using for DSM acquisition is not
capable of simultaneous recording of multiple echoes.
Currently, either the first or the last reflection of the emitted
laser pulse can be measured. Since this prevents the
measurement of the required data in a single pass coverage, the
flight effort for laser data capture is doubled, if one aims at the
acquisition of the first and last response of the emitted laser
pulse. Additionally, in our examples for some areas no response
could be measured at all in the last pulse mode. These regions
correspond to the white areas depicted in Figure 4. Besides
these sensor-related problems, a further differentiation of object
classes like the extraction of streets or different landuse classes
like grass-covered areas is not possible, if only laser data is
applied. For this reason, in our approach the height data is
integrated with multispectral imagery within a combined
classification step in order to separate the required objects.
3. CLASSIFICATION OF URBAN AREAS
3.1. Spectral Data
For the test site, color infrared (CIR) aerial images were
available, which were taken at a scale of 1:5000 with a normal
angle aerial camera. For digitization, the images were scanned
at a resolution of 60 p.m, resulting in three digital images in the
spectral bands near infrared, red and green with a pixel footprint
of 30 cm. The basic idea of the proposed algorithm is to
simultaneously use geometric and radiometric information by
applying a pixel-based classification. Within this classification,
the normalized DSM is used as an additional channel in
combination with the three spectral bands. For integration of
different data types, the first problem to be solved is the
registration of the datasets. In order to transform the data a
common system a colored ortho-image is generated from the
