Title :
Multiresolution Motion Planning for Autonomous Agents via Wavelet-Based Cell Decompositions
Author :
Cowlagi, R.V. ; Tsiotras, P.
Author_Institution :
Lab. for Inf. & Decision Syst., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
We present a path- and motion-planning scheme that is “multiresolution” both in the sense of representing the environment with high accuracy only locally and in the sense of addressing the vehicle kinematic and dynamic constraints only locally. The proposed scheme uses rectangular multiresolution cell decompositions, efficiently generated using the wavelet transform. The wavelet transform is widely used in signal and image processing, with emerging applications in autonomous sensing and perception systems. The proposed motion planner enables the simultaneous use of the wavelet transform in both the perception and in the motion-planning layers of vehicle autonomy, thus potentially reducing online computations. We rigorously prove the completeness of the proposed path-planning scheme, and we provide numerical simulation results to illustrate its efficacy.
Keywords :
discrete wavelet transforms; mobile robots; path planning; robot dynamics; robot kinematics; vehicles; autonomous agents; autonomous sensing system; completeness proving; dynamic constraint; environment representation; mobile robot; multiresolution motion planning; numerical simulation; path planning; perception system; rectangular multiresolution cell decomposition; vehicle autonomy; vehicle kinematic constraint; wavelet transform; wavelet-based cell decomposition; Approximation methods; Discrete wavelet transforms; Image resolution; Path planning; Planning; Signal resolution; Vehicles; Discrete wavelet transforms; dynamics; mobile robots; motion planning; path planning; Algorithms; Artificial Intelligence; Motion; Pattern Recognition, Automated; Robotics; Wavelet Analysis;
Journal_Title :
Systems, Man, and Cybernetics, Part B: Cybernetics, IEEE Transactions on
DOI :
10.1109/TSMCB.2012.2192268
