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Adaptive fuzzy sliding mode controller design for uncertain robotic manipulator with finite‐time convergence

Zhu, Yuqiang; Liu, Zhen; Kao, Yonggui; Zhu, Quanmin

Authors

Yuqiang Zhu

Zhen Liu

Yonggui Kao

Profile image of Quan Zhu

Quan Zhu Quan.Zhu@uwe.ac.uk
Professor in Control Systems



Abstract

ABSTRACTThis article investigates the issue of finite‐time tracking control for uncertain robotic manipulator systems with unknown actuator faults and shifting loads based upon a fuzzy sliding mode control strategy. A novel fuzzy adaptive sliding mode fault‐tolerant control law is synthesized, where a fuzzy approximation algorithm is utilized to fit the unknown plant parameters, potential disturbances, and relational actuator faults, and the corresponding adaptive robust term is designed to estimate the unidentified boundary of the estimated errors, and the boundedness of all the relevant design parameters of the manipulator systems is ensured combining with the average dwell time mechanism of switched system control theory. Furthermore, the reachability of the pre‐devised sliding surface and the finite‐time convergence of tracking error are achieved under the presented controller design. Ultimately, simulation results exhibit the feasibility and superiority of the proposed algorithm.

Journal Article Type Article
Acceptance Date Dec 1, 2024
Online Publication Date Dec 16, 2024
Publication Date Mar 31, 2025
Deposit Date Jan 19, 2025
Publicly Available Date Dec 17, 2025
Journal International Journal of Adaptive Control and Signal Processing
Print ISSN 0890-6327
Electronic ISSN 1099-1115
Publisher Wiley
Peer Reviewed Peer Reviewed
Volume 39
Issue 3
Pages 489-496
DOI https://doi.org/10.1002/acs.3952
Public URL https://uwe-repository.worktribe.com/output/13549665

Files

This file is under embargo until Dec 17, 2025 due to copyright reasons.

Contact Quan.Zhu@uwe.ac.uk to request a copy for personal use.




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