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Path-Integral-Based Reinforcement Learning Algorithm for Goal-Directed Locomotion of Snake-Shaped Robot

Yongqiang Qi, Yang Hailan, Rong Dan, Ke Yi, Lu Dongchen, Chunyang Li

Year
2021
Citations
5
Access
Open access

Abstract

This paper proposes a goal-directed locomotion method for a snake-shaped robot in 3D complex environment based on path-integral reinforcement learning. This method uses a model-free online Q-learning algorithm to evaluate action strategies and optimize decision-making through repeated “exploration-learning-utilization” processes to complete snake-shaped robot goal-directed locomotion in 3D complex environment. The proper locomotion control parameters such as joint angles and screw-drive velocities can be learned by path-integral reinforcement learning, and the learned parameters were successfully transferred to the snake-shaped robot. Simulation results show that the planned path can avoid all obstacles and reach the destination smoothly and swiftly.

Keywords

Reinforcement learningRobotPath (computing)Computer scienceMotion planningReinforcementRobot learningPath integral formulationAction (physics)Artificial intelligence

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