Litcius/Paper detail

Safe Multiagent Motion Planning Under Uncertainty for Drones Using Filtered Reinforcement Learning

Sleiman Safaoui, Abraham P. Vinod, Ankush Chakrabarty, Rien Quirynen, Yoshikawa Nobuyuki, Stefano Di Cairano

2024IEEE Transactions on Robotics19 citationsDOI

Abstract

We consider the problem of safe multi-agent motion planning for drones in uncertain, cluttered workspaces. For this problem, we present a tractable motion planner that builds upon the strengths of reinforcement learning and constrained-control-based trajectory planning. First, we use single-agent reinforcement learning to learn motion plans from data that reach the target but may not be collision-free. Next, we use a convex optimization, chance constraints, and set-based methods for constrained control to ensure safety, despite the uncertainty in the workspace, agent motion, and sensing. The proposed approach can handle state and control constraints on the agents, and enforce collision avoidance among themselves and with static obstacles in the workspace with high probability. The proposed approach yields a safe, real-time implementable, multi-agent motion planner that is simpler to train than methods based solely on learning. Numerical simulations and experiments show the efficacy of the approach.

Topics & Concepts

WorkspaceReinforcement learningMotion planningComputer scienceTrajectoryCollision avoidanceMotion (physics)Q-learningPlannerArtificial intelligenceSet (abstract data type)DroneMulti-agent systemRobotMathematical optimizationCollisionMathematicsAstronomyPhysicsComputer securityProgramming languageBiologyGeneticsRobotic Path Planning AlgorithmsReinforcement Learning in RoboticsDistributed Control Multi-Agent Systems