Full text: Papers accepted on the basis of peer-reviewed full manuscripts (Part A)

In: Paparoditis N., Pierrot-Deseilligny M.. Mallet C... Tournaire O. (Eds), 1APRS. Vol. XXXVIII. Part ЗА - Saint-Mandé, France. September 1-3. 2010 
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Figure 5: Global Energy Curve 
Figure 5 shows the corresponding global energy curve during 
the searching for optimal configuration. As can be seen from 
those figures, at the beginning, the global energy decreases 
quickly with the removal of false trees, and reaches the minima 
of global energy get at 42 iterations. Later, the global energy 
start to increase when trees are over-pruned, which indicates the 
effectiveness of the designed energy functions in our model. 
Finally, 127 trees arc detected from the CHM data. What we 
can interpret as well is that in the optimal configuration, the 
“false” treetops located on the crown edge and trees with over 
lapping crowns are removed at a high accuracy, when compared 
with the initial configuration. At the meantime, trees with big 
crown are kept even with some extend of overlaps. 
6. CONCLUSION AND FUTURE WORKS 
We have presented in this paper detecting individual trees from 
ALS data. The innovation of the method is formulating the tree 
detection in the data as a high-level MRF labeling problem, and 
highlights the problem representation and energy function de 
sign in the Markov Random Field model. In this approach, trees 
are modeled as objects with treetops, crown radius and some 
other features extracted from the data and the data is regarded 
as configurations of those objects. Then, neighborhood system 
is proposed to introduce relationships between the objects and 
energy functions are carefully designed to corporate the con 
straints in model. Finally, the optimal configuration is found 
through an energy minimization process. The experimental re 
sult shows a good detection rate of single trees in the data. 
The advantage of the method lies in that low level vision me 
thod is first used to extract priori information from the data, and 
trees are abstracted from that information in a high level. Then 
the problem is formulated using a Markov Random Field model. 
In such a way, the size of configuration space is greatly reduced 
and much less computation will be needed in the searching of 
optimal solution. Furthermore, under such a mathematic 
framework, other features or constraints extracted from data or 
even other sources, which help in the detection of trees, e.g. 
stems detected underneath the canopy cover, can be easily add 
ed and integrated into the current model without having to alter 
the structure of algorithm. However, there are still some issues 
to be studied in the future in order to improve the method. The 
first one will be model optimization. A RJMCMC embedded 
simulated annealing is suggested to be introduced for searching 
the configuration space more thoroughly to get the optimal con 
figuration. Secondly, it will also be interesting to explore some 
algorithm can be employed to help find best weighting coeffi 
cients automatically. Finally, more investigation will be imple 
mented to find out which scoring functions designed play more 
significant roles in the penalization of false trees and detection 
of true trees. Also, this method will be applied to more datasets 
to test its feasibility to forests of different types or structures. 
ACKNOWLEDGEMENTS 
This research was supported by a grant for a project entitled 
"Automated Change Detection of 3D Landscape Objects for 
Powerline Corridor Mapping by Integrating Airborne LiDAR 
and Multiple-viewing Digital Cameras” funded by Ontario 
Centres of Excellence and GeoDigitial International Inc. 
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