In: Paparoditis N., Pierrot-Deseilligny M.. Mallet C. Tournaire O. (Eds). 1APRS. Vol. XXXVIII. Part ЗА - Saint-Mandé, France. Septeniber 1-3. 2010
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4. CONCLUSIONS AND OUTLOOK
In this paper, an approach for the extraction of a road network
in suburban areas was presented. CIR images and a DSM were
used to first segment an image, then extract road parts and
connect them to finally form a road network. The results
presented in this paper show that the approach is suitable for the
extraction of a road network in a suburban scene. From all
examined subsets, three quarters of the road network could be
extracted, and more than 90% of the extracted roads were
correct. The approach was tested on two different data sets
(Grangemouth and Vaihingen). Despite the fact that the two
data sets had quite different sensor characteristics, we used
identical parameters for our road extraction algorithm, with the
exception of the NDVI threshold that had to be adapted
manually. This suggests that the parameter set is quite robust;
however, a further sensitivity analysis would be desirable.
Whereas the total completeness was lower in the Vaihingen data
set (mainly because the examined subsets there contained more
roads covered by trees), the correctness was consistently good,
which shows that the approach can be used for images from
different sensors and different suburban areas. An important
aspect to be improved is the geometric accuracy. This concerns
several parts of the algorithm. The extraction of the centre lines
from the irregularly shaped road parts could be improved by a
previous orientation-dependent smoothing of the road parts.
The junctions could be more explicitly modelled and their
verification could be enhanced by using context objects in a
similar way to that used for the subgraphs. When the network is
extracted, the geometric positions of the roads could be
improved using a snake-based algorithm. The completeness of
the network could be improved by a search for gaps in the
network and an evaluation of these gaps, e.g. by examining
valleys in the DSM starting from road ends.
ACKNOWLEDGEMENTS
The Vaihingen data set was provided by the German
Association for Photogrammetry and Remote Sensing (DGPF):
http://www.ifp.uni-stuttgart.de/dgpf/DKEP-Allg.html. The
normalized cuts calculation was adapted from a Matlab program
from T. Cour, S. Yu and J. Shi: http://www.seas.upenn.edu/
~timothee/software_ncut/software.html (accessed May 2010).
The linear program was calculated with the LP solver lp_solve:
http://lpsolve.sourceforge.net/5-5/ (accessed May 2010).
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