High-Order Internal Model-Based Iterative Learning Control for 2-D Linear FMMI Systems With Iteration-Varying Trajectory Tracking

IEEE Transactions on Systems Man and Cybernetics Part A-Systems and Humans Pub Date : 2021-03-01 DOI:10.1109/TSMC.2019.2897459

Kai Wan, Xiao-dong Li

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引用次数: 26

Abstract

This paper is concerned with iterative learning control (ILC) algorithms for two-dimensional (2-D) linear discrete systems described by the first Fornasini–Marchesini model (FMMI) with iteration-varying reference trajectories/profiles. The variation of reference trajectories in iteration domain is represented by a high-order internal model (HOIM) formula. Robustness and convergence of two types of HOIM-based ILC laws with different boundary conditions are investigated, respectively. A strategy employed in this paper is to reconstruct the HOIM-based ILC process of the 2-D linear FMMI system into a set of 2-D linear inequalities or a 2-D linear Roesser model such that sufficient robustness/convergence conditions of the HOIM-based ILC laws are obtained. Under random boundary conditions, the designed ILC law (9) is capable to drive the ILC tracking error into a bounded range. Moreover, under the HOIM-based boundary conditions, a perfect tracking to the iteration-varying reference trajectories can be achieved by utilizing the proposed ILC law (32). Two simulation examples are given to validate the effectiveness of the two proposed ILC algorithms.

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具有迭代变轨迹跟踪的二维线性FMMI系统的高阶内模迭代学习控制

本文研究了具有迭代变化参考轨迹/轮廓的第一个Fornasini-Marchesini模型(FMMI)所描述的二维线性离散系统的迭代学习控制(ILC)算法。参考轨迹在迭代域的变化用高阶内模(HOIM)公式表示。研究了不同边界条件下两类基于hoim的ILC律的鲁棒性和收敛性。本文采用的策略是将二维线性FMMI系统的基于hoim的ILC过程重构为一组二维线性不等式或二维线性Roesser模型，从而获得基于hoim的ILC律的充分鲁棒性/收敛性条件。在随机边界条件下，所设计的ILC律(9)能够将ILC跟踪误差驱动到有界范围内。此外，在基于hoim的边界条件下，利用所提出的ILC定律可以实现对迭代变化参考轨迹的完美跟踪(32)。通过两个仿真实例验证了所提出的两种ILC算法的有效性。

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.