CMRT09: Object Extraction for 3D City Models, Road Databases and Traffic Monitoring - Concepts, Algorithms, and Evaluation 
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inherent noise is reduced and underlying structures are enhanced 
depending on their length, their orientation or their intensity. 
In the image enhancement context this approach is most suitable 
for fine-structured areas, e.g. city centers. The main problem 
lies in the determination of thresholds for suppression and em 
phasis of structures. The determination of the threshold and the 
number of coefficients respectively is still experiential and highly 
dependent on the image content. If the scenes are reconstructed 
by a fix number of coefficients, the complexity of the scene is 
restricted. As the image description by the curvelet coefficients 
is purely based on structures, by omitting coefficients originally 
smooth areas are often affected by artifacts. At the moment the 
quadratic weighting of the single curvelet coefficients seems to 
be the best solution for fully automatic processing chains. 
The change detection approach provides excellent results in ur 
ban areas. The great advantage over pixel based methods is the 
sensitivity towards changes in structures and the possibility to 
predefine the scale and the strength of changes to be mapped. 
Problems occur in natural surroundings like forested areas, where 
the status of the foliage has an important seasonal impact on the 
backscattering behavior. Not to mention the weather conditions, 
snow cover with different moistures can highly modify the ap 
pearance in a SAR image. In consequence of that the interpre 
tation of the detected changes is very challenging. Although the 
change images contain clear structures without any disturbances, 
it is nearly impossible to distinguish man-made from natural, e.g. 
seasonal, changes, without a priori knowledge about the land 
cover. 
As the present results proved that two single polarized SAR im 
ages can be used to indicate changes happened to the imaged 
area, but they do not provide the information needed to interpret 
these changes, our future research will try to include other data 
sources into the processing chain. To discriminate natural cover 
from man-made objects, a coherence layer, that exploits the phase 
information of the input images could be helpful. Polarimetrie 
layers could facilitate the interpretation by attaching information 
about the scattering types to the detected changes. Apart from 
remote sensing data it is quite conceivable to introduce a priori 
knowledge by overlaying the change layer with land cover classi 
fications from optical data sources as well as with cadastral data 
sets. 
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