Reinforcement Learning Ship Autopilot: Sample efficient and Model Predictive Control-based Approach
Abstract
In this research we focus on developing a reinforcement learning system for a challenging task: autonomous control of a real-sized boat, with difficulties arising from large uncertainties in the challenging ocean environment and the extremely high cost of exploring and sampling with a real boat. To this end, we explore a novel Gaussian processes (GP) based reinforcement learning approach that combines sample-efficient model-based reinforcement learning and model predictive control (MPC). Our approach, sample-efficient probabilistic model predictive control (SPMPC), iteratively learns a Gaussian process dynamics model and uses it to efficiently update control signals within the MPC closed control loop. A system using SPMPC is built to efficiently learn an autopilot task. After investigating its performance in a simulation modeled upon real boat driving data, the proposed system successfully learns to drive a real-sized boat equipped with a single engine and sensors measuring GPS, speed, direction, and wind in an autopilot task without human demonstration.
Cite
@article{arxiv.1901.07905,
title = {Reinforcement Learning Ship Autopilot: Sample efficient and Model Predictive Control-based Approach},
author = {Yunduan Cui and Shigeki Osaki and Takamitsu Matsubara},
journal= {arXiv preprint arXiv:1901.07905},
year = {2024}
}
Comments
The 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS 2019)