具有多态不确定性和扰动的分数动力系统的分数模型误差补偿器设计方法

IF 1.8 3区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Ahmed Haddi, Mohamed El Azzouzi, Mohamed Laabissi
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引用次数: 0

摘要

我们提出了一种新颖的分数模型误差补偿器(FMEC)设计方法,以解决具有多态不确定性和干扰的分数动力系统中的模型误差难题。FMEC 可以有效补偿模型误差,从而提高控制系统的性能。该方法结合了 \(\mathcal{H}_\infty \)-norm准则和粒子群优化(PSO)算法来优化补偿器设计。该方法整合了用于鲁棒性能评估的 \(\mathcal{H}_\infty\)-norm 准则和用于优化的 PSO。通过对分数动态系统进行数值模拟,验证了所提出的 FMEC 设计。这些仿真表明,该设计成功地补偿了模型误差,提高了控制系统的整体性能。这项研究为设计适用于各种工程领域的鲁棒 FMEC 提供了一个实用的解决方案,尤其适用于易受多态不确定性和干扰影响的系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A design approach of fractional model error compensator for fractional dynamical systems with polytopic uncertainty and disturbance

A design approach of fractional model error compensator for fractional dynamical systems with polytopic uncertainty and disturbance

We present a novel design methodology for a fractional model error compensator (FMEC) that addresses the challenge of model errors in fractional dynamical systems with polytopic uncertainty and disturbances. The FMEC can effectively compensate for model errors, thereby enhancing the performance of control systems. This approach leverages a combination of \(\mathcal{H}_\infty \)-norm criteria and the Particle Swarm Optimization (PSO) algorithm to optimize the compensator design. The methodology integrates \(\mathcal{H}_\infty \)-norm criteria for robust performance evaluation and PSO for optimization. The proposed FMEC design is validated through numerical simulations conducted on a fractional dynamical system. These simulations demonstrate that the design successfully compensates for model errors and improves the overall performance of the control system. This study offers a practical solution for designing robust FMECs applicable in various engineering fields, particularly for systems susceptible to polytopic uncertainty and disturbances.

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来源期刊
Circuits, Systems and Signal Processing
Circuits, Systems and Signal Processing 工程技术-工程:电子与电气
CiteScore
4.80
自引率
13.00%
发文量
321
审稿时长
4.6 months
期刊介绍: Rapid developments in the analog and digital processing of signals for communication, control, and computer systems have made the theory of electrical circuits and signal processing a burgeoning area of research and design. The aim of Circuits, Systems, and Signal Processing (CSSP) is to help meet the needs of outlets for significant research papers and state-of-the-art review articles in the area. The scope of the journal is broad, ranging from mathematical foundations to practical engineering design. It encompasses, but is not limited to, such topics as linear and nonlinear networks, distributed circuits and systems, multi-dimensional signals and systems, analog filters and signal processing, digital filters and signal processing, statistical signal processing, multimedia, computer aided design, graph theory, neural systems, communication circuits and systems, and VLSI signal processing. The Editorial Board is international, and papers are welcome from throughout the world. The journal is devoted primarily to research papers, but survey, expository, and tutorial papers are also published. Circuits, Systems, and Signal Processing (CSSP) is published twelve times annually.
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