具有致动器死区的随机约束非线性系统的实用快速有限时间稳定性

IF 3.4 2区数学 Q1 MATHEMATICS, APPLIED

Communications in Nonlinear Science and Numerical Simulation Pub Date : 2024-08-26 DOI:10.1016/j.cnsns.2024.108293

Lifang Qiu , Junsheng Zhao , Zong-Yao Sun

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引用次数: 0

摘要

随机约束非线性系统受到量化效应和致动器死区的影响，本文探讨了如何为随机约束非线性系统实现实际快速有限时间稳定的挑战。为解决这些问题，本文引入了自适应参数化和部分控制策略，旨在有效逼近和抵消非线性干扰。尽管存在不确定性，这种方法仍能确保受控系统在有限时间内稳健稳定。此外，我们还提出了一种新颖的障碍函数，可减轻通常由边界函数施加的限制，同时还能利用模糊逻辑系统来妥善管理非线性项。在这些创新的基础上，我们提出了一个新定理，专门用于随机非线性系统的实际快速有限时间控制机制。我们通过一个涉及电流控制直流电机系统的示例，证明了我们的理论发展的有效性，展示了所提出的控制方案的实际应用性和鲁棒性。

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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Practically fast finite-time stability of stochastic constrained nonlinear systems with actuator dead zone

This article addresses the challenge of achieving practically fast finite-time stabilization for stochastic constrained nonlinear systems, which are subject to both quantization effects and actuator dead zones. To tackle these issues, adaptive parameterization and partial control strategies are introduced with the aim of efficiently approximating and counteracting nonlinear disturbances. This approach ensures the robust stabilization of the controlled system within a finite time frame, despite the presence of uncertainties. Additionally, a novel barrier function is propose that mitigates the constraints usually imposed by boundary functions, while also leveraging a fuzzy logic system to manage nonlinear terms adeptly. Building on these innovations, we formulate a new theorem dedicated to practically fast finite-time control mechanisms for stochastic nonlinear systems. The efficacy of our theoretical developments is substantiated through an illustrative example involving a current-controlled DC motor system, demonstrating the practical applicability and robustness of the proposed control scheme.

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来源期刊

Communications in Nonlinear Science and Numerical Simulation MATHEMATICS, APPLIED-MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

CiteScore

6.80

自引率

7.70%

发文量

378

审稿时长

78 days

期刊介绍： The journal publishes original research findings on experimental observation, mathematical modeling, theoretical analysis and numerical simulation, for more accurate description, better prediction or novel application, of nonlinear phenomena in science and engineering. It offers a venue for researchers to make rapid exchange of ideas and techniques in nonlinear science and complexity. The submission of manuscripts with cross-disciplinary approaches in nonlinear science and complexity is particularly encouraged. Topics of interest: Nonlinear differential or delay equations, Lie group analysis and asymptotic methods, Discontinuous systems, Fractals, Fractional calculus and dynamics, Nonlinear effects in quantum mechanics, Nonlinear stochastic processes, Experimental nonlinear science, Time-series and signal analysis, Computational methods and simulations in nonlinear science and engineering, Control of dynamical systems, Synchronization, Lyapunov analysis, High-dimensional chaos and turbulence, Chaos in Hamiltonian systems, Integrable systems and solitons, Collective behavior in many-body systems, Biological physics and networks, Nonlinear mechanical systems, Complex systems and complexity. No length limitation for contributions is set, but only concisely written manuscripts are published. Brief papers are published on the basis of Rapid Communications. Discussions of previously published papers are welcome.