We address the problem of modeling complex target behavior using a stochastic model that integrates object dynamics, statistics gathered from the environment and semantic knowledge about the scene. The method exploits prior knowledge to build point-wise polar histograms that provide the ability to forecast target motion to the most likely paths. Physical constraints are included in the model through a ray-launching procedure, while semantic scene segmentation is used to provide a coarser representation of the most likely crossable areas. The model is enhanced with statistics extracted from previously observed trajectories and with nearly-constant velocity dynamics. Information regarding the target's destination may also be included steering the prediction to a predetermined area. Our experimental results, validated in comparison to actual targets' trajectories, demonstrate that our approach can be effective in forecasting objects' behavior in structured scenes.
Point-based path prediction from polar histograms / P. Coscia, F. Castaldo, F.A.N. Palmieri, L. Ballan, A. Alahi, S. Savarese - In: FUSION 2016[s.l] : Institute of Electrical and Electronics Engineers (IEEE), 2016. - ISBN 978-0-9964-5274-8. - pp. 1961-1967 (( Intervento presentato al 19. convegno International Conference on Information Fusion : July, 5 - 8 tenutosi a Heidelberg (Germany) nel 2016.
Point-based path prediction from polar histograms
P. Coscia
Primo
;
2016
Abstract
We address the problem of modeling complex target behavior using a stochastic model that integrates object dynamics, statistics gathered from the environment and semantic knowledge about the scene. The method exploits prior knowledge to build point-wise polar histograms that provide the ability to forecast target motion to the most likely paths. Physical constraints are included in the model through a ray-launching procedure, while semantic scene segmentation is used to provide a coarser representation of the most likely crossable areas. The model is enhanced with statistics extracted from previously observed trajectories and with nearly-constant velocity dynamics. Information regarding the target's destination may also be included steering the prediction to a predetermined area. Our experimental results, validated in comparison to actual targets' trajectories, demonstrate that our approach can be effective in forecasting objects' behavior in structured scenes.
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