具有扩散项的分数阶时滞神经网络同步的间歇边界控制

Intermittent Boundary Control for Synchronization of Fractional Delay Neural Networks With Diffusion Terms

IEEE Transactions on Systems, Man, and Cybernetics: Systems · 2022
被引 32
ABS 3

中文导读

研究了通过连续和间歇边界控制器实现耦合分数阶时滞反应扩散神经网络的同步,设计了基于状态和观测器的控制器,并分析了时滞和控制时长对同步的影响。

Abstract

This article studies the synchronization of new coupled fractional delayed reaction–diffusion neural networks with reaction terms satisfying the global Lipschitz condition via time-continuous and time-discontinuous boundary controllers. The realization of neural networks inevitably involves diffusion phenomena and time delays, and all the neurons of neural networks are interrelated. Considering these aspects, this study focuses on coupled fractional neural networks with time-delay and diffusion terms. A state-dependent boundary control (BC) is designed for when the state information is available, and a criterion is presented to ensure the synchronization of the considered systems. Considering the advantages of a time-discontinuous controller, an intermittent BC and a criterion of synchronization are given. When the state information cannot be fully obtained, a boundary-output-based observer is provided for estimating the states. Then, an observer-based intermittent boundary controller is given to ensure the synchronization. From the given criteria, the effects of time delay and the control time length on synchronization are analyzed. This research involves two key challenges: 1) consideration of the BC and intermittent control parameters in the system performance analysis and 2) clarification of the influence of system parameters on synchronization. These challenges are addressed using Poincaré’s inequality, the fractional Razumikhin-type theorem, and several properties of the Mittag-Leffler function are used to deal with the above difficulties. Examples show that our results are valid.

分数阶神经网络同步控制边界控制间歇控制时滞系统