The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part B5. Beijing 2008
Figure 9. Scatter plot of angle of pivoting v.s. walking speed
956
Figure 7. Calculated probability density distribution
Figure 8. Extracted prominently congested area
3.4 Statistics of Walking Characteristics
On the basis of tracking results, the relationships between
walking speeds, angle of pivoting are derived. Figure 9 denotes
the scatter plot for angle of pivoting v.s. walking speeds. As the
result of Figure 9, the data have almost 2 clusters that one
shows low walking speed but angle of pivoting has large
variance, and the other shows the range from 0.5 to 2.0 of
walking speed and relatively small variance. We found when
pedestrians change their walking directions, pedestrians slow
down their walking speed.
0 1 2 3 4 5
walking speed [m/sec]
4. CONCLUSION
In this paper, .a people tracking method by using multiple laser
range scanners is proposed, which is relatively robust than
cameras in congested situation. Moreover, based on the
obtained trajectories, crowds flow characteristics such as traffic
density, walking velocity and directionality, a degree of
intercrossing, and those relativity are analyzed as the
probability density by using kernel density estimation method.
Additionally, by calculating the uniformity of trajectories’
directions and the traffic volume, prominently congested areas
are extracted. Finally, we conclude our proposed method should
be effective to analyze crowds flow characteristics on the real
time basis even if the target space is relatively wide and
congested situation such as railway station or shopping mall.
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