In: Wagner W„ Sz^kely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
objects (e.g. cars, buildings, individual trees, or brushwood)
within the point-cloud.
In any case, sophisticated classification is necessary. For the
extraction of a DTM, various algorithms were developed (cf.
Briese, 2010). All of them have in common that they study the
local geometric properties of the acquired ALS points. Other
information, which could help to improve classification, is
rarely utilized.
With the advent of full-waveform (FWF)-ALS systems (Hug et
al. 2004, Wagner et al., 2004) additional interesting observables
for an advanced classification of the FWF-ALS data have
become available. Doneus and Briese (2006) demonstrate the
advanced capabilities of FWF-ALS data for the generation of
digital terrain models (DTM) in vegetated areas. The echo width
determined from the FWF information was used to support the
classification of the ALS data into terrain and off-terrain points
in the presence of low vegetation. Miicke (2009) extended the
utilisation of the echo width by introducing a weighting scheme
that depends next to the increase of the echo width on the echo
amplitude. In both examples, utilizing information from FWF-
ALS could improve the quality of the estimated DTM.
FWF-ALS therefore seems to be a very promising approach to
enhance the quality of both DTMs and digital object models
(DOM). However, it is still in its infancy. In contrast to
conventional ALS sensors FWF-ALS is just available since a
few years and extended processing chains still have to be
developed. Especially the complex interaction of the laser beam
with different types of vegetation cover has to be better
understood. Enhanced knowledge in this field, i.e. an in-depth
understanding of the FWF-information will improve both
quality and reliability of DTMs. This is especially desirable in
areas with low vegetation. Furthermore, the investigations
should lead to advanced geometric models that allow a more
reliable automated analysis, which is desirable for different
applications (hydrology, etc. as well as archaeology).
This paper can be seen as a first step towards a detailed study of
the interaction between FWF-laser beams and various objects
within a vegetation complex. For the analysis a vegetated area
was simultaneously scanned by airborne and terrestrial (TLS)
laser scanning on a calm day. After presenting the study area,
we will focus on the process of co-geo-referencing the ALS and
TLS data sets. In section 4 and 5, some preliminary results of
the analysis of the FWF-ALS data set are presented and
discussed.
2. STUDY SITE AND DATA ACQUISITION
For the study of the FWF-ALS data, a small area (approx.
2.25km 2 , cf. Figure 1) was selected in the Leithagebirge,
approx. 30km south of Vienna. This area is already well known
by the authors due to a small FWF-ALS mission in 2006
(Doneus and Briese, 2006) and a large archaeological FWF
ALS data acquisition campaign carried out in 2007 (cf. Doneus
et al, 2008). It contains a large building complex of a former
monastery (“St. Anna in der Wüste”) in the central northern
part. The buildings are encircled by an open meadow which is
enclosed by a forest with understory of varying density.
Figure 1. Study Site “St. Anna in der Wüste” in the area of the
Leithagebirge (30km in the south of Vienna) with the planned
flight lines (approx, length: 1.5km) for the ALS data
acquisition. © Google 2010
Figure 2. Left: Shading of a digital surface model (DSM,
0.25m raster) of the main area of interest (370m by 370m)
derived from the ALS data; Right: DSM shading and TLS data
(red).
The data acquisition of the site took place on the 10 th of
December 2009 in leaf off condition. It was a day with no wind.
This was important to exclude the effect of wind on the
vegetation canopy and facilitate the co-registration of the
simultaneously performed TLS and ALS scans. The FWF-ALS
data set was acquired during a test flight of the company RIEGL
Laser Measurement Systems GmbH with the novel FWF-ALS
sensor RIEGL LMS-Q680 (Riegl, 2010). The area was covered
by six strips (both three strips in perpendicular directions) with
a flying height of approx. 500m above ground. This resulted in
an ALS point density of approx. 20 last echo points/m 2 . A
shading of the resulting digital surface model is displayed in the
left part of Figure 2.
The TLS data acquisition took place simultaneously to the ALS
flight. The TLS data was acquired by a Riegl VZ-400
instrument with online waveform processing capability (cf.
Riegl, 2010; Pfennigbauer and Ullrich, 2010). Additionally to
the TLS data, images were acquired by an attached digital
camera (Nikon D300). Altogether, data from 16 stations were
acquired near the north eastern part of the monastery (cf. right
part of Figure 2). For an advanced geo-referencing of the ALS
and TLS data (see section 3), some of the stations covered the
monasteries’ inclined planar roof areas with different
exposition. Furthermore, reflector targets were used in order to
perform a relative orientation/registration of the individual
stations.
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