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Autores principales: Jia, Xinyu, Yang, Jun, Lu, Kaixin, Pan, Yongping, Yu, Haoyong
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2306.02742
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author Jia, Xinyu
Yang, Jun
Lu, Kaixin
Pan, Yongping
Yu, Haoyong
author_facet Jia, Xinyu
Yang, Jun
Lu, Kaixin
Pan, Yongping
Yu, Haoyong
contents To achieve high-accuracy manipulation in the presence of unknown disturbances, we propose two novel efficient and robust motion control schemes for high-dimensional robot manipulators. Both controllers incorporate an unknown system dynamics estimator (USDE) to estimate disturbances without requiring acceleration signals and the inverse of inertia matrix. Then, based on the USDE framework, an adaptive-gain controller and a super-twisting sliding mode controller are designed to speed up the convergence of tracking errors and strengthen anti-perturbation ability. The former aims to enhance feedback portions through error-driven control gains, while the latter exploits finite-time convergence of discontinuous switching terms. We analyze the boundedness of control signals and the stability of the closed-loop system in theory, and conduct real hardware experiments on a robot manipulator with seven degrees of freedom (DoF). Experimental results verify the effectiveness and improved performance of the proposed controllers, and also show the feasibility of implementation on high-dimensional robots.
format Preprint
id arxiv_https___arxiv_org_abs_2306_02742
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Enhanced Robust Motion Control based on Unknown System Dynamics Estimator for Robot Manipulators
Jia, Xinyu
Yang, Jun
Lu, Kaixin
Pan, Yongping
Yu, Haoyong
Robotics
To achieve high-accuracy manipulation in the presence of unknown disturbances, we propose two novel efficient and robust motion control schemes for high-dimensional robot manipulators. Both controllers incorporate an unknown system dynamics estimator (USDE) to estimate disturbances without requiring acceleration signals and the inverse of inertia matrix. Then, based on the USDE framework, an adaptive-gain controller and a super-twisting sliding mode controller are designed to speed up the convergence of tracking errors and strengthen anti-perturbation ability. The former aims to enhance feedback portions through error-driven control gains, while the latter exploits finite-time convergence of discontinuous switching terms. We analyze the boundedness of control signals and the stability of the closed-loop system in theory, and conduct real hardware experiments on a robot manipulator with seven degrees of freedom (DoF). Experimental results verify the effectiveness and improved performance of the proposed controllers, and also show the feasibility of implementation on high-dimensional robots.
title Enhanced Robust Motion Control based on Unknown System Dynamics Estimator for Robot Manipulators
topic Robotics
url https://arxiv.org/abs/2306.02742