Output Regulation Based on Zero-Sum Game for Discrete-Time System Driven by Exogenous Signal

IF 8.6 1区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Systems Man Cybernetics-Systems Pub Date : 2025-04-25 DOI:10.1109/TSMC.2025.3560421

Ruizhuo Song;Gaofu Yang;Frank L. Lewis

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引用次数: 0

Abstract

This article proposes a novel Q-learning algorithm that relies solely on input-output data to address the output regulation control problem of complex discrete-time systems affected by exogenous signals. Unlike traditional methods, this algorithm does not require detailed system information, state knowledge, or data about external systems or exogenous signals. Additionally, the control strategy does not depend on state information, but on input-output data processed by a set of filters. We provide upper and lower bounds on the discount factor, eliminating the need to solve the Riccati equation. These bounds ensure that the value function remains finite, and we prove the stability of the system when using control inputs derived from the value function with the given discount factor. Furthermore, the Q-learning algorithm, when applied with input data containing probing noise, is shown to yield Q-function estimates that are independent of the probing noise. Finally, a simulation involving a grid-connected inverter is presented, demonstrating the effectiveness of the proposed algorithm in a practical setting.

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基于零和博弈的外源信号驱动离散时间系统输出调节

针对受外源信号影响的复杂离散系统的输出调节控制问题，提出了一种新的仅依赖输入输出数据的q -学习算法。与传统方法不同，该算法不需要详细的系统信息、状态知识或有关外部系统或外生信号的数据。此外，控制策略不依赖于状态信息，而是依赖于一组过滤器处理的输入输出数据。我们提供了折现因子的上界和下界，消除了解里卡蒂方程的需要。这些边界保证了值函数是有限的，并且我们证明了当使用由给定折现因子的值函数导出的控制输入时系统的稳定性。此外，当q -学习算法应用于包含探测噪声的输入数据时，显示出与探测噪声无关的q函数估计。最后，给出了并网逆变器的仿真，验证了该算法在实际环境中的有效性。

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 Cybernetics-Systems AUTOMATION & CONTROL SYSTEMS-COMPUTER SCIENCE, CYBERNETICS

CiteScore

18.50

自引率

11.50%

发文量

812

审稿时长

6 months

期刊介绍： The IEEE Transactions on Systems, Man, and Cybernetics: Systems encompasses the fields of systems engineering, covering issue formulation, analysis, and modeling throughout the systems engineering lifecycle phases. It addresses decision-making, issue interpretation, systems management, processes, and various methods such as optimization, modeling, and simulation in the development and deployment of large systems.