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Self-Configuring Robot Path Planning With Obstacle Avoidance via Deep Reinforcement Learning

Bianca Sangiovanni, Gian Paolo Incremona, Marco Piastra, Antonella Ferrara

2020IEEE Control Systems Letters111 citationsDOIOpen Access PDF

Abstract

This letter proposes a hybrid control methodology to achieve full body collision avoidance in anthropomorphic robot manipulators. The proposal improves classical motion planning algorithms by introducing a Deep Reinforcement Learning (DRL) approach trained ad hoc for performing obstacle avoidance, while achieving a reaching task in the operative space. More specifically, a switching mechanism is enabled whenever a condition of proximity to the obstacles is met, thus conferring to the dual-mode architecture a self-configuring capability in order to cope with objects unexpectedly invading the workspace. The proposal has been finally tested relying on a realistic robot manipulator simulated in a V-REP environment.

Topics & Concepts

Reinforcement learningObstacle avoidanceCollision avoidanceWorkspaceComputer scienceMotion planningRobotObstacleQ-learningTask (project management)Artificial intelligencePath (computing)Dual (grammatical number)Mobile robotSimulationCollisionEngineeringComputer networkPolitical scienceLawLiteratureArtComputer securitySystems engineeringRobot Manipulation and LearningModular Robots and Swarm IntelligenceReinforcement Learning in Robotics
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