Litcius/Paper detail

A Two-Stage Reinforcement Learning Approach for Multi-UAV Collision Avoidance Under Imperfect Sensing

Dawei Wang, Tingxiang Fan, Tao Han, Jia Pan

2020IEEE Robotics and Automation Letters138 citationsDOI

Abstract

Unlike autonomous ground vehicles (AGVs), unmanned aerial vehicles (UAVs) have a higher dimensional configuration space, which makes the motion planning of multi-UAVs a challenging task. In addition, uncertainties and noises are more significant in UAV scenarios, which increases the difficulty of autonomous navigation for multi-UAV. In this letter, we proposed a two-stage reinforcement learning (RL) based multi-UAV collision avoidance approach without explicitly modeling the uncertainty and noise in the environment. Our goal is to train a policy to plan a collision-free trajectory by leveraging local noisy observations. However, the reinforcement learned collision avoidance policies usually suffer from high variance and low reproducibility, because unlike supervised learning, RL does not have a fixed training set with ground-truth labels. To address these issues, we introduced a two-stage training method for RL based collision avoidance. For the first stage, we optimize the policy using a supervised training method with a loss function that encourages the agent to follow the well-known reciprocal collision avoidance strategy. For the second stage, we use policy gradient to refine the policy. We validate our policy in a variety of simulated scenarios, and the extensive numerical simulations demonstrate that our policy can generate time-efficient and collision-free paths under imperfect sensing, and can well handle noisy local observations with unknown noise levels.

Topics & Concepts

Reinforcement learningCollision avoidanceComputer scienceTrajectoryCollisionNoise (video)Artificial intelligenceTask (project management)ImperfectSet (abstract data type)Ground truthEngineeringComputer securityProgramming languageImage (mathematics)LinguisticsPhysicsAstronomyPhilosophySystems engineeringEvacuation and Crowd DynamicsRobotic Path Planning AlgorithmsReinforcement Learning in Robotics