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Decentralized Task and Path Planning for Multi-Robot Systems

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arxiv 2011.10034 v1 pith:425PGGUJ submitted 2020-11-19 cs.RO cs.MA

Decentralized Task and Path Planning for Multi-Robot Systems

classification cs.RO cs.MA
keywords taskmarkovallocationmodulepathplanningdecentralizeddecision
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We consider a multi-robot system with a team of collaborative robots and multiple tasks that emerges over time. We propose a fully decentralized task and path planning (DTPP) framework consisting of a task allocation module and a localized path planning module. Each task is modeled as a Markov Decision Process (MDP) or a Mixed Observed Markov Decision Process (MOMDP) depending on whether full states or partial states are observable. The task allocation module then aims at maximizing the expected pure reward (reward minus cost) of the robotic team. We fuse the Markov model into a factor graph formulation so that the task allocation can be decentrally solved using the max-sum algorithm. Each robot agent follows the optimal policy synthesized for the Markov model and we propose a localized forward dynamic programming scheme that resolves conflicts between agents and avoids collisions. The proposed framework is demonstrated with high fidelity ROS simulations and experiments with multiple ground robots.

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