TY - GEN
T1 - Scalable asymptotically-optimal multi-robot motion planning
AU - Dobson, Andrew
AU - Solovey, Kiril
AU - Shome, Rahul
AU - Halperin, Dan
AU - Bekris, Kostas E.
N1 - Funding Information:
K. Solovey and D. Halperin are with the Computer Science Dept. of Tel Aviv University, Israel, {kirilsol,danha}@post.tau.ac.il. Their work has been supported in part by the Israel Science Foundation (grant no. 825/15) and by the Blavatnik Computer Science Research Fund. K. S. has also been supported by the Clore Israel Foundation.
Funding Information:
A. Dobson, R. Shome and K. Bekris are with the Computer Science Dept. of Rutgers Univ., NJ, USA, {chuples.dobson, rahul.shome, kostas.bekris}@cs.rutgers.edu. They were supported by NSF IIS 1451737, IIS-1617744 and CCF 1330789.
Publisher Copyright:
© 2017 IEEE.
PY - 2018/1/8
Y1 - 2018/1/8
N2 - Discovering high-quality paths for multirobot problems can be achieved, in principle, by exploring the composite space of all robots. For instance, samplingbased algorithms that build either roadmaps or tree data structures achieve asymptotic optimality. The hardness of motion planning, however, which implies an exponential dependence on problem dimensionality, renders the explicit construction of such structures in the composite space of all robots impractical. This work proposes a scalable, sampling-based planner for coupled multi-robot problems that provides desirable path-quality guarantees. The proposed dRRT∗ is an informed, asymptotically-optimal extension of a prior method dRRT, which introduced the idea of building roadmaps for each robot and implicitly searching the tensor product of these structures in the composite space. The paper describes the conditions for convergence to optimal paths in multi-robot problems, which is not feasible for the prior method. Moreover, simulations indicate dRRT∗ converges to high-quality paths and scales to higher numbers of robots where various alternatives fail. It can also be used on high-dimensional challenges, such as planning for robot manipulators.
AB - Discovering high-quality paths for multirobot problems can be achieved, in principle, by exploring the composite space of all robots. For instance, samplingbased algorithms that build either roadmaps or tree data structures achieve asymptotic optimality. The hardness of motion planning, however, which implies an exponential dependence on problem dimensionality, renders the explicit construction of such structures in the composite space of all robots impractical. This work proposes a scalable, sampling-based planner for coupled multi-robot problems that provides desirable path-quality guarantees. The proposed dRRT∗ is an informed, asymptotically-optimal extension of a prior method dRRT, which introduced the idea of building roadmaps for each robot and implicitly searching the tensor product of these structures in the composite space. The paper describes the conditions for convergence to optimal paths in multi-robot problems, which is not feasible for the prior method. Moreover, simulations indicate dRRT∗ converges to high-quality paths and scales to higher numbers of robots where various alternatives fail. It can also be used on high-dimensional challenges, such as planning for robot manipulators.
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U2 - 10.1109/MRS.2017.8250940
DO - 10.1109/MRS.2017.8250940
M3 - Conference contribution
AN - SCOPUS:85044470045
T3 - 2017 International Symposium on Multi-Robot and Multi-Agent Systems, MRS 2017
SP - 120
EP - 127
BT - 2017 International Symposium on Multi-Robot and Multi-Agent Systems, MRS 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2017 International Symposium on Multi-Robot and Multi-Agent Systems, MRS 2017
Y2 - 4 December 2017 through 5 December 2017
ER -