基于生物多目标优化的分数阶预测反馈控制策略的分数阶能源供需超混沌系统有限时间同步

IF 1.9 4区 工程技术 Q3 ENGINEERING, MECHANICAL
A. Soukkou, Y. Soukkou, S. Haddad, M. Benghanem, A. Rabhi
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引用次数: 2

摘要

本文利用分数阶控制(F-oC)的概念实现分数阶动力系统的同步。本文研究的系统反映了上海地区能源供需关系复杂的真实物理现象。在此基础上,给出了所开发的分数阶能量吸引子,以及在相同分数阶能量吸引子控制律下的同步仿真结果。请注意,大多数同步方法在处理复杂连续系统时都取得了优异的性能;然而,就我们所知,没有一种方法能解决基于F-oC和现代优化技术的分数阶能源系统的同步问题。通过设计有限时间控制理论,研究了两个相同分数阶能源供需超混沌系统的有限时间全同步问题。建立了基于超前预测的分数阶控制律(Pb-FoCL),用于f - overerdshss的有限时间同步。在满足预期性能要求的情况下,设计过程成为对所开发控制器知识库进行多目标优化的问题。利用有限时间李雅普诺夫稳定性理论证明了控制环系统的有限时间稳定性。在此基础上,利用改进的人工蜂鸟算法(I-AHA),在满足设计约束条件的同时,找到了最优的pcb - focl知识库。仿真结果验证了所提控制策略的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Finite-time Synchronization of Fractional-order Energy Resources Demand-Supply Hyperchaotic Systems via Fractional-order Prediction-based Feedback Control Strategy with Bio-inspired Multiobjective Optimization
The concept of fractional-order control (F-oC) is exploited in this paper to synchronize fractional-order dynamical systems. The addressed systems in this paper reflect the real physical phenomena characterized by the complicated relationship between supply and demand for energy resources in the Shanghai area. Thus, we provide the developed fractional energy resource attractor and the simulation results regarding synchronization under the proposed control law of the same fractional energy resource attractor. Note that most of the synchronization methods achieved excellent performance when dealing with complex continuous systems; however, no method addressed the synchronization problem of fractional-order energy resource systems based on the F-oC and modern optimization techniques, to the best of our knowledge. By designing the finite-time control theory, the finite-time full synchronization of two identical fractional-order energy resources demand-supply hyperchaotic systems (F-oERDSHSs) is investigated due to its performance. The advanced prediction-based fractional-order control law (Pb-FoCL) is established for finite-time synchronization of F-oERDSHSs. The design procedure becomes a multiobjective optimization problem of the knowledge base of the developed controller while satisfying the desired performance requirements. The Finite-Time Stability (F-TS) of the control-loop system is proved by using the finite-time Lyapunov stability theory. Furthermore, the Improved Artificial Hummingbird Algorithm (I-AHA) is used to find an optimal knowledge base of Pb-FoCL while achieving the design constraints. Simulation results are provided to verify the efficiency of the proposed control strategy.
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来源期刊
CiteScore
4.00
自引率
10.00%
发文量
72
审稿时长
6-12 weeks
期刊介绍: The purpose of the Journal of Computational and Nonlinear Dynamics is to provide a medium for rapid dissemination of original research results in theoretical as well as applied computational and nonlinear dynamics. The journal serves as a forum for the exchange of new ideas and applications in computational, rigid and flexible multi-body system dynamics and all aspects (analytical, numerical, and experimental) of dynamics associated with nonlinear systems. The broad scope of the journal encompasses all computational and nonlinear problems occurring in aeronautical, biological, electrical, mechanical, physical, and structural systems.
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