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Auteurs principaux: Xu, Junhong, Yin, Kai, Chen, Zheng, Gregory, Jason M., Stump, Ethan A., Liu, Lantao
Format: Preprint
Publié: 2021
Sujets:
Accès en ligne:https://arxiv.org/abs/2111.08748
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author Xu, Junhong
Yin, Kai
Chen, Zheng
Gregory, Jason M.
Stump, Ethan A.
Liu, Lantao
author_facet Xu, Junhong
Yin, Kai
Chen, Zheng
Gregory, Jason M.
Stump, Ethan A.
Liu, Lantao
contents We propose a diffusion approximation method to the continuous-state Markov Decision Processes (MDPs) that can be utilized to address autonomous navigation and control in unstructured off-road environments. In contrast to most decision-theoretic planning frameworks that assume fully known state transition models, we design a method that eliminates such a strong assumption that is often extremely difficult to engineer in reality. We first take the second-order Taylor expansion of the value function. The Bellman optimality equation is then approximated by a partial differential equation, which only relies on the first and second moments of the transition model. By combining the kernel representation of the value function, we design an efficient policy iteration algorithm whose policy evaluation step can be represented as a linear system of equations characterized by a finite set of supporting states. We first validate the proposed method through extensive simulations in 2D obstacle avoidance and 2.5D terrain navigation problems. The results show that the proposed approach leads to a much superior performance over several baselines. We then develop a system that integrates our decision-making framework with onboard perception and conduct real-world experiments in both cluttered indoor and unstructured outdoor environments. The results from the physical systems further demonstrate the applicability of our method in challenging real-world environments.
format Preprint
id arxiv_https___arxiv_org_abs_2111_08748
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Kernel-based diffusion approximated Markov decision processes for autonomous navigation and control on unstructured terrains
Xu, Junhong
Yin, Kai
Chen, Zheng
Gregory, Jason M.
Stump, Ethan A.
Liu, Lantao
Robotics
We propose a diffusion approximation method to the continuous-state Markov Decision Processes (MDPs) that can be utilized to address autonomous navigation and control in unstructured off-road environments. In contrast to most decision-theoretic planning frameworks that assume fully known state transition models, we design a method that eliminates such a strong assumption that is often extremely difficult to engineer in reality. We first take the second-order Taylor expansion of the value function. The Bellman optimality equation is then approximated by a partial differential equation, which only relies on the first and second moments of the transition model. By combining the kernel representation of the value function, we design an efficient policy iteration algorithm whose policy evaluation step can be represented as a linear system of equations characterized by a finite set of supporting states. We first validate the proposed method through extensive simulations in 2D obstacle avoidance and 2.5D terrain navigation problems. The results show that the proposed approach leads to a much superior performance over several baselines. We then develop a system that integrates our decision-making framework with onboard perception and conduct real-world experiments in both cluttered indoor and unstructured outdoor environments. The results from the physical systems further demonstrate the applicability of our method in challenging real-world environments.
title Kernel-based diffusion approximated Markov decision processes for autonomous navigation and control on unstructured terrains
topic Robotics
url https://arxiv.org/abs/2111.08748