Full text: Technical Commission VII (B7)

  
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
that the differences between samples in different sectors is 
significant over sector 1 (forest) and the other sectors. Sector 3 is 
also significantly different from the other sectors except sector 
2. This can be explained on the fact that the area in sector 3 has 
stems of deadwood standing, thus the height distribution is 
different from the other sectors, where all stems were cut down. 
The method was not able to discriminate between sectors 2, 4 
and 5. The low vegetation present and the sample area size do 
not bring enough height variance between them for 
discrimination. A solution could be to use smaller sample plots 
over more representative spots, avoiding the inclusion of a large 
percent of bare ground in the plot. A stratified sampling 
procedure using image interpretation could be used to segment 
an image masking the ground area. 
  
  
SI S2 S3 S4 S5 
S1 | - 0;56* 046% 043* 0:32* 
S2 - 0.36 0.19 0.12 
S3 - 0.41*  0.47* 
S4 - 0.11 
S5 - 
  
  
*Indicates a significant difference in distributions at a — 0.05 
Table 3. Characteristics of the four test sectors. 
  
Figure 4. Top — 3D view of plot without ground returns — the 
scale reports the intensity in 8 bit scale. Bottom - four slices 
from the voxel grid reporting digitizer counts of waveform. 
526 
Another factor to consider is that the sampling of the waveform 
occured with a nominal threshold which was chosen according 
to the observed values. This was possible because we worked on 
a single survey and thus the survey characteristics which 
influence the outgoing energy for every pulse — thus the return 
energy loss — where relatively constant (relative flying height, 
pulse frequency). A more objective method would be to 
calculate only the segment with Full Width at Half Maximum 
(FWHM) criteria. 
4. CONCLUSIONS 
The results are part of a more in-depth investigation for 
evaluating methods for discriminating low vegetation 
distribution over land for defining the effect of re-forestation 
methods in a broader ongoing project which investigates 
vegetation dynamics in areas which have been part of a severe 
fire event. A positive result over the sampled areas will enable 
to apply the method and evaluate results over larger areas to test 
for robustness. The proposed modifications mentioned in the 
discussion will be applied to test for improved results. The final 
objective is to provide a method to segment 3D space into 
significant information using waveform data. 
5. ACKNOWLEDGEMENTS 
This work is part of the CPDA097420 project funded by the 
University of Padua: "Disturbi naturali in foreste alpine: 
approccio  multiscala e applicazioni LiDAR", scientific 
coordinator prof. Emanuele Lingua. 
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