Adaptive Fuzzy Full-State and Output-Feedback Control for Uncertain Robots With Output Constraint

IEEE Transactions on Systems Man and Cybernetics Part A-Systems and Humans Pub Date : 2021-11-01 DOI:10.1109/tsmc.2019.2963072

Xinbo Yu, Wei He, Hongyi Li, Jian Sun

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引用次数: 137

Abstract

This article focuses on the tracking control issue of robotic systems with dynamic uncertainties. To enhance tracking accuracy in a robotic manipulator with uncertainties, an adaptive fuzzy full-state feedback control is proposed. In view of output-feedback control with unknown states, a high-gain observer is employed to estimate unknown states. Considering the particular requirement that output of systems should be constrained in some practical working fields, we further design adaptive fuzzy full-state and output-feedback control schemes with output constraint to ensure that output maintains in constrained regions. By applying the Lyapunov theory, it is guaranteed that closed-loop systems are semiglobally uniformly ultimately bounded (SGUUB). Tangent-type barrier Lyapunov function is used for the controller design with output constraint and ensure stability. Finally, the effectiveness of our proposed methods is shown through both simulation examples and experimental results, comparative experiments in Baxter robot are proposed for evaluating the practicability of our proposed methods in actual applications.

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带输出约束的不确定机器人自适应模糊全状态输出反馈控制

本文主要研究具有动态不确定性的机器人系统的跟踪控制问题。为了提高不确定机器人的跟踪精度，提出了一种自适应模糊全状态反馈控制方法。针对未知状态的输出反馈控制，采用高增益观测器对未知状态进行估计。考虑到某些实际工作领域对系统输出有约束的特殊要求，进一步设计了带输出约束的自适应模糊全状态和输出反馈控制方案，以保证系统在约束区域内保持输出。利用李雅普诺夫理论，保证了闭环系统是半全局一致最终有界的。采用切线型势垒Lyapunov函数设计具有输出约束的控制器，保证了控制器的稳定性。最后，通过仿真算例和实验结果验证了所提方法的有效性，并在Baxter机器人上进行了对比实验，以评估所提方法在实际应用中的实用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Systems Man and Cybernetics Part A-Systems and Humans 工程技术-计算机：控制论

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审稿时长

6.0 months

期刊介绍： The scope of the IEEE Transactions on Systems, Man, and Cybernetics: Systems includes the fields of systems engineering. It includes issue formulation, analysis and modeling, decision making, and issue interpretation for any of the systems engineering lifecycle phases associated with the definition, development, and deployment of large systems. In addition, it includes systems management, systems engineering processes, and a variety of systems engineering methods such as optimization, modeling and simulation.