Reduced-Order Estimator-Based Efficient Fault-Tolerant Tracking Control Optimization for Constrained LPV Systems

IEEE Transactions on Systems Man and Cybernetics Part A-Systems and Humans Pub Date : 2021-09-01 DOI:10.1109/TSMC.2019.2957301

Kezhen Han, Jian Feng

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引用次数: 2

Abstract

This article focuses on addressing a fault-tolerant tracking control (FTTC) problem for a class of constrained polytopic LPV systems. The dual-mode predictive control method is introduced to design an efficient FTTC strategy such that the performance output of LPV systems can be regulated to track a given reference within state/input constraints. On the whole, the FTTC policy is constructed by the reduced-order estimator, tracking error feedback, double signal compensation, and optimal predictive regulation (PR). In specific, a novel reduced-order estimator is first designed to provide the state and fault information. Then, an unconstrained robust tracking error feedback control is designed to stabilize the LPV systems. Following that, a double signal compensation mechanism is proposed to remove the influences of fault, fault estimation error and other mismatched disturbances. Afterward, an optimal PR policy is further designed to optimize the tracking performance and handle system constraints. Finally, the effectiveness of these proposed results is verified by three case studies.

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基于降阶估计的约束LPV系统高效容错跟踪控制优化

本文主要研究一类约束多边形LPV系统的容错跟踪控制问题。引入双模预测控制方法设计了一种有效的FTTC策略，使LPV系统的性能输出可以在状态/输入约束下进行调节以跟踪给定的参考。总体而言，FTTC策略由降阶估计器、跟踪误差反馈、双信号补偿和最优预测调节(PR)组成。具体来说，首先设计了一种新的降阶估计器来提供状态和故障信息。然后，设计了无约束鲁棒跟踪误差反馈控制来稳定LPV系统。然后，提出了一种双信号补偿机制，以消除故障、故障估计误差和其他不匹配干扰的影响。然后，进一步设计最优PR策略以优化跟踪性能并处理系统约束。最后，通过三个案例验证了所提结果的有效性。

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.