随机摄动周期奇异摄动系统的自适应神经滑模控制

IF 6.4 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Automation Science and Engineering Pub Date : 2024-12-13 DOI:10.1109/TASE.2024.3513314

Jun Cheng;Shan Liu;Huaicheng Yan;Ju H. Park

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引用次数: 0

摘要

研究了采样数据奇异摄动系统在随机摄动周期和无限制欺骗攻击下的自适应神经网络滑模控制问题。与传统的转移概率相比，逗留概率的利用对于捕获与采样周期相关的固有随机性至关重要。此外，在存在无限制欺骗攻击的情况下，采用基于神经网络的方法来估计和减轻其对系统性能的影响。此外，还设计了基于采样周期模式和奇异摄动参数的滑模控制器。该控制器保证了闭环系统在均方意义上的指数极限有界性和指定滑动面的可达性。最后，通过实例验证了所提理论的有效性和合理性。从业者须知-由于数字时代的到来，定期采样数据系统受到了很多关注。然而，在实际工程条件下，往往会引入非理想因素，如网络拥塞、噪声干扰、电压不稳定等，从而导致随机扰动采样。本文考虑采用更容易用统计方法得到的逗留概率来模拟采样周期的变化。另一方面，在真实的网络环境中，攻击者注入攻击的有界性是无法保证的。因此，在本文中，我们考虑使用基于神经网络的方法来估计和减轻它们在存在无限制欺骗攻击时对系统性能的影响。同时，利用滑模控制实现被控系统在均方意义上的指数极限有界性和指定滑动面的可达性，滑模控制因其成本节约和可靠性而受到广泛关注。

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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Adaptive Neural Sliding Mode Control for Singularly Perturbed Systems With Randomly Perturbed Sampling Periods

This paper addresses the problem of adaptive neural network sliding mode control for sampled-data singularly perturbed systems subjected to randomly perturbed sampling periods and unrestricted deception attacks. In contrast to the conventional transition probabilities,the utilization of sojourn probabilities are essential to capture the inherent randomness associated with the sampling periods. Furthermore, in the presence of unrestricted deception attacks, a neural network-based approach is utilized to estimate and mitigate their impact on system performance. Additionally, a sliding mode controller is developed based on both the sampling period mode and the singularly perturbed parameter. This controller ensures the exponential ultimate boundedness in the mean square sense and the reachability of the specified sliding surface for the closed-loop system. Finally, the proposed theory is validated through a practical example, demonstrating its effectiveness and soundness. Note to Practitioners — Due to the advent of the digital era, periodically sampled-data systems have received much attention. However, practical engineering conditions often introduce non-ideal factors, such as network congestion, noise interference, and voltage instability, which can cause randomly perturbed sampling. As considered in this paper, a sojourn probability, which is more easily obtained by statistical methods, is applied to model the variation of sampling periods. On the other hand, in real network environments, the boundedness of an attacker’s injection attack cannot be guaranteed. Therefore, in this paper, we consider using a neural network-based approach to estimate and mitigate their impact on system performance in the presence of unrestricted deception attacks. Meanwhile, sliding mode control, which has drawn widespread attention for its cost-saving and reliability, is utilized to achieve exponential ultimate boundedness in the mean square sense and reachability of the specified sliding surface of the controlled system.

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来源期刊

IEEE Transactions on Automation Science and Engineering 工程技术-自动化与控制系统

CiteScore

12.50

自引率

14.30%

发文量

404

审稿时长

3.0 months

期刊介绍： The IEEE Transactions on Automation Science and Engineering (T-ASE) publishes fundamental papers on Automation, emphasizing scientific results that advance efficiency, quality, productivity, and reliability. T-ASE encourages interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, operations research, and other fields. T-ASE welcomes results relevant to industries such as agriculture, biotechnology, healthcare, home automation, maintenance, manufacturing, pharmaceuticals, retail, security, service, supply chains, and transportation. T-ASE addresses a research community willing to integrate knowledge across disciplines and industries. For this purpose, each paper includes a Note to Practitioners that summarizes how its results can be applied or how they might be extended to apply in practice.