In comparison with echo signals between Japanese cedar and 
Zelkova serrata, the initial slope of the first peak of Zelkova 
serrata was steeper than that of Japanese cedar. Crown shapes 
of Japanese cedar and Zelkova serrata are the conical- and the 
bowled-shaped, respectively. We considered that the reason of 
the difference was the shape of crown. As the results, we 
considered that the developed simulator was able to simulate the 
difference of shape of crown well. 
7.2 The effects of the illumination angle and the slope of 
the ground 
Figure 3 is the effect of the illumination angle and the slope 
of the ground. Figure (a), (b), (c) and (d) stands for scenario 
no.l, no.2, no.3 and no.5, respectively. Full width half 
maximum (FWHM) of (b) became wider than that of (a), since 
optical paths between these were changed. In comparison with 
between (a) and (c), the echo signal of (c) differed significantly 
from (a). FWHM of the first peak of (c) was wider and the 
second peak had two peaks. On the other hand, in case of (d), 
the two peaks of the second peak in (c) disappeared in (d). 
  
Folative tens: 
Relative snc ty 
  
  
  
  
  
  
  
  
  
  
(d) 
Figure 3. The effect of the illumination angle and the slope of 
the ground. (a), (b), (c) and (d) stands for scenario no.1, no.2, 
no.3 and no.5, respectively. 
7.3 Comprehend of the elementary process of the 
generation of echo signal using the visualization tool 
It is difficult to understand the elementary process between 
the laser beams and the object using only the results of the echo 
signal. For example, in case of scenario no.3, the second peak 
had two. However, in case of scenario no.5, two peaks 
disappeared. Then, the reason was considered using the 
visualization tool. Figure 4 shows the results of visualization of 
intersections derived from scenario no.2 (a) and no.5 (b). Sub 
windows stands for view at different directions, respectively. 
The upper left window is top view, the upper right window is 
left view, the bottom left window is right view and the bottom 
right window is perspective view. Dot symbol is intersections 
between sub laser beams and objects. As a result of analysis of 
intersections on the objects, two peaks corresponded to the 
distribution of intersections (bottom left view of (a)). There 
were two areas which had high density intersections on the 
surface of the ground. On the other hand, in case of figure 4 (b), 
high density area was one (bottom left view of (a)). The 
visualization tool was able to help to comprehend the 
elementary process of the generation of echo signal. 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
    
    
  
  
  
  
  
  
   
  
   
   
  
  
  
  
  
  
   
   
   
  
  
  
    
   
  
  
  
  
  
  
  
  
  
  
  
  
  
    
    
    
   
    
   
   
   
    
   
  
    
TE Y 
  
(b) 
Figure 4. The results of visualization of intersections derived 
from scenario no.2 (a) and no.5 (b) 
8. CONCLUSIONS 
A waveform simulation model for complex forest 
environments using 3D object was presented in this paper. 
Since the echo signal depends on the sensor configuration, the 
target structure and terrain condition, we implemented these 
features in the simulator. According to the simulation using 
scenarios, these results indicated that the simulator was able to 
generate the echo signal under various conditions. Moreover, 
the visualization tool indicated that it was quite useful for 
understanding the elementary process of the generation of echo 
signal. 
However, the simulator is preliminary result and we have not 
evaluated the simulator by an actual data yet. Moreover, an 
effect of noise has not been validated. 
In our future work, we plan to evaluate the simulator by using 
an actual data. 
References 
Clark, M. L., Clark, D. B., and Roberts, D. A., 2004. Small- 
footprint LiDAR estimation of sub-canopy elevation and tree 
height in a tropical rain forest landscape. Remote sensing of 
Environment, 91, 68-89. 
Goodwin, N R., Coops, N. C., and Culvenor, D. S., 2007. 
Development of a simulation model to predict LiDAR 
interception in forested environments. Remote sensing of 
Environment, 111, 481-492. 
Næasset, E., 2004. Effects of different flying altitudes on 
biophysical stand properties estimated form canopy height and 
density measured with a small footprint scanning laser. Remote 
sensing of Environment, 91, 243-255. 
Sun, G., and Ranson, K. J., 2000. Modelling LiDAR returns 
from forest canopies. IEEE Transactions on Geoscience and 
Remote Sensing, 38, 2617-2626. 
  
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