通过非周期性间歇引脚控制实现带噪声复杂网络的连续滞后同步

IF 2.1 3区 计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS Systems & Control Letters Pub Date : 2024-06-08 DOI:10.1016/j.sysconle.2024.105842
Xiaowen Lu , Mengchen Wang , Qi Yang , Zhongjun Ma , Jun Cheng , Kezan Li
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引用次数: 0

摘要

连续滞后同步(SLS)是一种新颖而重要的同步模式,其控制问题在过去几年中得到了深入研究。然而,噪声扰动对 SLS 控制的影响仍不明确。为此,本文重点研究了具有噪声扰动的动态网络上 SLS 的间歇钉控。为了将 SLS 推向理想轨迹,我们设计了一种间歇性针刺控制方案,该方案仅在受控区间和小部分节点上有效。通过应用随机微分方程的稳定性理论,我们得到了网络能够实现均方指数稳定性 SLS 的充分条件。根据这些条件,我们可以确定哪些节点应受控制、最小控制比以及噪声扰动对 SLS 的影响。一个有趣的发现是,对每个子区间至少一半的节点进行控制可以确保 SLS 的随机稳定性,而这种稳定性与任何网络参数无关。通过耦合 Chua 电路网络验证了所提出的间歇引脚控制方案的有效性。
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Successive lag synchronization of a complex network with noise via aperiodically intermittent pinning control

Successive lag synchronization (SLS) is a novel and important synchronization pattern, whose control problem has been deeply investigated in the past several years. However, the impact of noise perturbation on the control of SLS is still unclear. To this end, this paper focuses on the intermittent pinning control of SLS on a dynamical network with noise perturbation. In order to push the SLS to a desired trajectory, we design an intermittent pinning control scheme that is active only on controlled intervals and a small proportion of nodes. By applying the stability theory of stochastic differential equation, we obtain sufficient conditions under which the network can realize the SLS with exponential stability in mean square. According to these conditions, we can determine which nodes should be controlled or not, the minimum control ratio and the impact of noise perturbation on the SLS. An interesting finding is that performing the control on at least half of each subinterval can ensure the stochastic stability of SLS, which is independent of any network parameters. The effectiveness of proposed intermittent pinning control scheme is verified by the network of coupled Chua’s circuits.

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来源期刊
Systems & Control Letters
Systems & Control Letters 工程技术-运筹学与管理科学
CiteScore
4.60
自引率
3.80%
发文量
144
审稿时长
6 months
期刊介绍: Founded in 1981 by two of the pre-eminent control theorists, Roger Brockett and Jan Willems, Systems & Control Letters is one of the leading journals in the field of control theory. The aim of the journal is to allow dissemination of relatively concise but highly original contributions whose high initial quality enables a relatively rapid review process. All aspects of the fields of systems and control are covered, especially mathematically-oriented and theoretical papers that have a clear relevance to engineering, physical and biological sciences, and even economics. Application-oriented papers with sophisticated and rigorous mathematical elements are also welcome.
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