International Archives of the Phot« 
  
erammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
  
  
  
  
  
5.2 Results 
4 
re the method was able 
first examples are taken 
We start this section with examples whe 
to generate a DTM of good quality. Th 
from the Eggenburg data set. Fi; | shows a shading of a 
DSM acquired by image matching with MATCH-T before 
filtering with SCOP++ in an area in the east of Eggenburg. 
Figure 5 shows the DTM that could be derived by hierarchical 
robust filtering. 
  
  
  
  
  
Figure 5. Shaded view of a DTM after including break lines 
and filtering with SCOP++ (Eggenburg east). The 
DSM is shown in figure 1. 
The influence of the off-terrain points on houses could be 
eliminated completely. Even large buildings such as a factory in 
the left lower part and blocks of houses in the right upper part 
of the test area could be eliminated successfully. This was 
mainly achieved by choosing a rather coarse resolution of 15 m 
for thinning out the data in the first iteration, at the cost of a 
degree of smoothing that cut off some terrain features. If these 
smoothing effects are too large to be tolerated for the 
application of the DTM, break lines determined by interactive 
measurement can be considered in the filtering process. Thus, 
these smoothing effects can be avoided. 
It was interesting to observe that using a high degree of 
smoothing in image matching smoothed the DSM at houses and 
trees without completely eliminating them. As a result, some 
off-terrain points were classified as terrain points by robust 
filtering because houses were not accentuated enough to be 
distinguished from the terrain. We think that it would be easier 
to select the appropriate parameters in each step of our filter 
strategy if the smoothing parameter were set to ‘low’ in image 
matching. Actually, it would be desirable not to filter or smooth 
the original data at all, to achieve a point distribution closer to 
the one delivered by ALS. 
Figure 6 shows the result for another area in Eggenburg. The 
terrain is more undulating than in the example in figure 5, with 
some abrupt changes along a railway line and dense vegetation 
in the left lower part of the scene. Off-terrain points on houses 
could be eliminated again, but hierarchical robust filtering could 
not remove the off-terrain points in the dense forest south of the 
railway line. As predicted in section 4.1, this was caused by the 
lack of terrain points delivered by image matching. This 
problem could only be circumvented by manual measurement of 
3D points on the terrain in the forest, which is, however, hardly 
feasible. 
We selected the town centre of Eggenburg to check the 
performance of our method in a densely built-up area (figure 7). 
In the densely built-up area in the left lower part of the scene 
+ 418 
only a few terrain points were delivered by MATCH-T. The 
grid width for the first thinning of the data had to be chosen 
rather wide (30 m) in order to cope with large areas without any 
terrain points. Still, it was not possible to get as good a DTM as 
in the more rural areas of the previous examples. The reason for 
this is the lack of terrain points in inner courtyards and narrow 
streets between the houses. However, the influence of the off- 
terrain points on the houses could be eliminated and a DTM of 
quite a good quality could be achieved. Again, unwanted 
smoothing effects could be reduced by introducing break lines. 
  
m. 
Figure 6. Shaded view of a DSM from image matching (left) 
and the resulting DTM after including break lines 
and filtering (right) (Eggenburg west). 
  
Figure 7. Shaded views of an elevation grid acquired by 
MATCH-T (left) and of a DTM after filtering (right) 
for the city centre of Eggenburg; contour lines in the 
DTM are shown. 
Finally, we want to present some examples where our method 
failed to eliminate the influence of the off-terrain points. In the 
example taken from the waste disposal site near Stockerau, the 
influence of off-terrain points on buildings and vehicles should 
have been eliminated. The terrain contained small features such 
as heaps of sand and waste (figure 8). As the shapes and 
dimensions of the buildings are nearly the same as those of the 
terrain, no satisfying result could be achieved. The filtering 
method either eliminated both the buildings and heaps of sand 
and waste material, or it eliminated neither of them. It is, 
however, no surprise that the method only works if there is à 
distinction in appearance between the terrain and the objects 
that should be eliminated. 
  
Internatio 
UH iiid 
Figure 8. 
  
Figure 9. 
The Schn 
filtering 
wooded a 
of the ele 
10 m. Co 
way than 
very few 
grid widt 
The para: 
restrictive 
possible 
coarsely : 
represent: 
iteration, 
above th 
below th 
original | 
using the 
Monnet 
parametet 
(h = 
above the 
off-terrair 
  
ing 
few terra 
alanrith 
algorithm 
— 
e 
c 
Image m: 
was obvic