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Abstract

This paper formulates a new minimum constraint removal (MCR) motion planning problem in which the objective is to remove the fewest geometric constraints necessary to connect a start and goal state with a free path. It describes a probabilistic roadmap motion planner for MCR in continuous configuration spaces that operates by constructing increasingly refined roadmaps, and efficiently solves discrete MCR problems on these networks. A number of new theoretical results are given for discrete MCR, including a proof that it is NP-hard by reduction from SET-COVER. Two search algorithms are described that perform well in practice. The motion planner is proven to produce the optimal MCR with probability approaching 1 as more time is spent, and its convergence rate is improved with various efficient sampling strategies. It is demonstrated on three example applications: generating human-interpretable excuses for failure, motion planning under uncertainty, and rearranging movable obstacles.

Keywords

Motion planning computational complexity configuration space robot manipulators

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References

Basch

Guibas

Hsu

Nguyen

(2001) Disconnection proofs for motion planning. In: IEEE International conference on robotics and automation, Seoul, Korea, pp. 1765–1772.

Bretl

Lall

Latombe

Rock

(2004) Multi-step motion planning for free-climbing robots. In: Workshop on the Algorithmic Foundations of Robotics, Zeist, the Netherlands.

Canny

(1988) Complexity of Robot Motion Planning. Cambridge, MA: MIT Press.

Dogar

Srinivasa

(2011) A framework for push–grasping in clutter. In: Robotics: Science and Systems.

Erickson

LaValle

(2013) A simple, but np-hard, motion planning problem. In: Proceedings of the twenty-seventh AAAI conference on artificial intelligence (AAAI-13).

Frigioni

Marchetti-Spaccamela

Nanni

(2000) Fully dynamic algorithms for maintaining shortest paths trees. Journal of Algorithms 34(2): 251–281. DOI: 10.1006/ jagm.1999.1048.

Göbelbecker

Keller

Eyerich

Brenner

Nebel

(2010) Coming up with good excuses: What to do when no plan can be found. In: International conference on automated planning and scheduling.

Hsu

Latombe

Motwani

(1997) Path planning in expansive configuration spaces. In: IEEE International conference on robotics and automation pp. 2219–2226.

Huang

Gupta

(2009) Collision-probability constrained PRM for a manipulator with base pose uncertainty. In: IEEE/RSJ International conference on intelligent robotic systems, pp. 1426–1432.

10.

Karaman

Frazzoli

(2010) Incremental sampling-based algorithms for optimal motion planning. In: Robotics: Science and Systems (RSS), Zaragoza, Spain.

11.

LaValle

Kuffner

Jr (2001) Randomized kinodynamic planning. The International Journal of Robotics Research 20: 379–400.

12.

Lund

Yannakakis

(1994) On the hardness of approximating minimization problems. Journal of the ACM 41: 960-981. DOI: 10.1145/185675.306789.

13.

McCarthy

Bretl

Hutchinson

(2012) Proving path non-existence using sampling and alpha shapes. In: IEEE International conference on robotics and automation.

14.

Plaku

(2012) Planning robot motions to satisfy linear temporal logic, geometric, and differential constraints. In: ICAPS 2012 Workshop on Combining Task and Motion Planning for Real-World Applications, Sao Paolo, Brazil.

15.

Plaku

Hager

(2010) Sampling-based motion planning with symbolic, geometric, and differential constraints. In: IEEE International conference on robotics and automation, Anchorage, AK.

16.

Prosser

(1996) An empirical study of phase transitions in binary constraint satisfaction problems. Artificial Intelligence 81: 81–109.

17.

Reif

(1979) Complexity of the mover’s problem and generalizations. In: 20th annual IEEE symposium on foundations of computer science, San Juan, Puerto Rico, pp. 421–427.

18.

Stilman

Kuffner

(2005) Navigation among movable obstacles: real-time reasoning in complex environments. International Journal of Humanoid Robotics 2: 479–504.

19.

Vazirani

(2001) Approximation Algorithms. Berlin: Springer-Verlag.

20.

Zhang

Kim

Manocha

(2008) A simple path non-existence algorithm using c-obstacle query. In: Akella

Amato

Huang

Mishra

(eds.), Algorithmic Foundation of Robotics VII (Springer Tracts in Advanced Robotics, vol. 47). Berlin: Springer, pp. 269–284.

The minimum constraint removal problem with three robotics applications

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