Deep Reinforcement Learning with Enhanced PPO for Safe Mobile Robot Navigation
Abstract
Collision-free motion is essential for mobile robots. Most approaches to collision-free and efficient navigation with wheeled robots require parameter tuning by experts to obtain good navigation behavior. This study investigates the application of deep reinforcement learning to train a mobile robot for autonomous navigation in a complex environment. The robot utilizes LiDAR sensor data and a deep neural network to generate control signals guiding it toward a specified target while avoiding obstacles. We employ two reinforcement learning algorithms in the Gazebo simulation environment: Deep Deterministic Policy Gradient and proximal policy optimization. The study introduces an enhanced neural network structure in the Proximal Policy Optimization algorithm to boost performance, accompanied by a well-designed reward function to improve algorithm efficacy. Experimental results conducted in both obstacle and obstacle-free environments underscore the effectiveness of the proposed approach. This research significantly contributes to the advancement of autonomous robotics in complex environments through the application of deep reinforcement learning.
Cite
@article{arxiv.2405.16266,
title = {Deep Reinforcement Learning with Enhanced PPO for Safe Mobile Robot Navigation},
author = {Hamid Taheri and Seyed Rasoul Hosseini and Mohammad Ali Nekoui},
journal= {arXiv preprint arXiv:2405.16266},
year = {2024}
}
Comments
This paper is under review by Int. J. of Intelligent Machines and Robotics