Title :
Obstacle avoidance using hierarchical dynamic programming
Author :
Peterson, James K.
Author_Institution :
Clemson Univ., SC, USA
Abstract :
Studies the problem of finding the optimal path or trajectory of a robot or other unmanned device through an obstacle field for a given start and goal position. In the most general problem, the obstacle field would be modeled by a finite array of time dependent analog valued pixels. Moreover since the field of vision of the unmanned device is limited, the authors could not assume perfect knowledge of the full obstacle field at any given time. The author discuss approximate optimal paths constructed using hierarchical methods. The hierarchical methods entail constructing a coarse resolution version of the original obstacle array and then using multipass dynamic programming to find an optimal coarse path
Keywords :
dynamic programming; mobile robots; planning (artificial intelligence); coarse resolution; hierarchical dynamic programming; mobile robot; multipass dynamic programming; obstacle avoidance; optimal coarse path; optimal path; optimal trajectory; path planning; unmanned device; Computer architecture; Costs; Dynamic programming; Engines; Grid computing; H infinity control; Information filtering; Information filters; Neural networks; Shape;
Conference_Titel :
System Theory, 1991. Proceedings., Twenty-Third Southeastern Symposium on
Conference_Location :
Columbia, SC
Print_ISBN :
0-8186-2190-7
DOI :
10.1109/SSST.1991.138545
