18 
CMRT09: Object Extraction for 3D City Models, Road Databases and Traffic Monitoring - Concepts, Algorithms, and Evaluation 
The best orientation for a road is chosen by minimizing the num 
ber of extracted segments (as shown in Fig.9); a road can be de 
fined as the minimum set of segments with a length greater than 
T2 and same angular value. The set of segments which forms 
a road is created applying a clustering algorithm; the DBSCAN 
(Ester et al., 1996) is adopted to group the set of extracted seg 
ments. A segment belongs to a cluster if and only if the distance 
between the initial point of segment and the nearest neighbour is 
under a threshold; if this geometric criteria is satisfied the lengths 
of clusterized segments are also checked. If the length are compa 
rable (in terms of distance from the mean value of the cluster) the 
set of cluster is labelled as road and the centerline is calculated. 
In Fig. 10 a series of tests on Mannheim data-set for different 
orientations is shown. Tests put in evidence that the algorithm, 
owing to the clustering, does not consider incoherent segments 
(Fig. 10c). 
a) b) C) 
Figure 10: Road extraction for three different angles; segments 
are the thick red lines (bottom), while raw ones are shown in top 
The extracted geo-referenced and vectorial road graph with the 
proposed technique is shown in Fig.l 1; some roads are not cor 
rectly identified due to presence of high density canopies. 
Figure 11 : Road graph for Mannheim data-set 
5 CONCLUSIONS AND FUTURE WORK 
In this paper, we presented a complete methodology to solve the 
problem of automatic extraction of urban objects from multi 
source aerial data. The procedure, which consists of sequential 
steps, takes advantage of classified data with a powerful machine 
learning algorithm as AdaBoost with CART as weak learner. The 
capability of distinguishing among four classes in an urban area 
as Mannheim increases the set of possible applications; two test 
cases were presented: building and road extraction. In the case of 
building extraction, the fusion of spectral data with LiDAR data 
using AdaBoost overtakes the limits of a simple nDSM thresh 
olding especially when canopies have a high density. The pro 
posed road extraction method allows to reduce the effect of oc- 
clusions;roads, extracted with the “line growing” approach en 
hanced with clustering, well match with a photo-interpretation 
process. As future works, more tests on more complex data with 
curved lines will be performed; moreover different weak learners 
based on RBF Neural Networks will be tested. 
ACKNOWLEDGMENT 
We would like to thank C. Nardinocchi and K. Khoshelham at 
Delft University of Technology for their helpful support. 
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