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Main Authors: Xu, Junhong, Yin, Kai, Gregory, Jason M., Hauser, Kris, Liu, Lantao
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.14956
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author Xu, Junhong
Yin, Kai
Gregory, Jason M.
Hauser, Kris
Liu, Lantao
author_facet Xu, Junhong
Yin, Kai
Gregory, Jason M.
Hauser, Kris
Liu, Lantao
contents Navigation safety is critical for many autonomous systems such as self-driving vehicles in an urban environment. It requires an explicit consideration of boundary constraints that describe the borders of any infeasible, non-navigable, or unsafe regions. We propose a principled boundary-aware safe stochastic planning framework with promising results. Our method generates a value function that can strictly distinguish the state values between free (safe) and non-navigable (boundary) spaces in the continuous state, naturally leading to a safe boundary-aware policy. At the core of our solution lies a seamless integration of finite elements and kernel-based functions, where the finite elements allow us to characterize safety-critical states' borders accurately, and the kernel-based function speeds up computation for the non-safety-critical states. The proposed method was evaluated through extensive simulations and demonstrated safe navigation behaviors in mobile navigation tasks. Additionally, we demonstrate that our approach can maneuver safely and efficiently in cluttered real-world environments using a ground vehicle with strong external disturbances, such as navigating on a slippery floor and against external human intervention.
format Preprint
id arxiv_https___arxiv_org_abs_2403_14956
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Boundary-Aware Value Function Generation for Safe Stochastic Motion Planning
Xu, Junhong
Yin, Kai
Gregory, Jason M.
Hauser, Kris
Liu, Lantao
Robotics
Navigation safety is critical for many autonomous systems such as self-driving vehicles in an urban environment. It requires an explicit consideration of boundary constraints that describe the borders of any infeasible, non-navigable, or unsafe regions. We propose a principled boundary-aware safe stochastic planning framework with promising results. Our method generates a value function that can strictly distinguish the state values between free (safe) and non-navigable (boundary) spaces in the continuous state, naturally leading to a safe boundary-aware policy. At the core of our solution lies a seamless integration of finite elements and kernel-based functions, where the finite elements allow us to characterize safety-critical states' borders accurately, and the kernel-based function speeds up computation for the non-safety-critical states. The proposed method was evaluated through extensive simulations and demonstrated safe navigation behaviors in mobile navigation tasks. Additionally, we demonstrate that our approach can maneuver safely and efficiently in cluttered real-world environments using a ground vehicle with strong external disturbances, such as navigating on a slippery floor and against external human intervention.
title Boundary-Aware Value Function Generation for Safe Stochastic Motion Planning
topic Robotics
url https://arxiv.org/abs/2403.14956