Synchronization and pinning control of stochastic coevolving networks

IF 7.3 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

Annual Reviews in Control Pub Date : 2022-01-01 DOI:10.1016/j.arcontrol.2022.04.005

Fabio Della Rossa , Pietro De Lellis

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引用次数: 10

Abstract

Network dynamical systems are often characterized by the interlaced evolution of the node and edge dynamics, which are driven by both deterministic and stochastic factors. This manuscript offers a general mathematical model of coevolving network, which associates a state variable to each node and edge in the network, and describes their evolution through coupled stochastic differential equations. We study the emergence of synchronization, be it spontaneous or induced by a pinning control action, and provide sufficient conditions for local and global convergence. We enable the use of the Master Stability Function approach for studying coevolving networks, thereby obtaining conditions for almost sure local exponential convergence, whereas global conditions are derived using a Lyapunov-based approach. The theoretical results are then leveraged to design synchronization and pinning control protocols in two select applications. In the first one, the edge dynamics are tailored to induce spontaneous synchronization, whereas in the second the pinning edges are activated/deactivated and their weights modulated to drive the network towards the pinner’s trajectory in a distributed fashion.

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随机协同进化网络的同步与固定控制

网络动力系统通常具有节点和边缘动态交错演化的特征，这种演化是由确定性和随机因素共同驱动的。本文提出了一个共同进化网络的一般数学模型，该模型将一个状态变量关联到网络中的每个节点和边缘，并通过耦合随机微分方程描述它们的演化。我们研究了同步的出现，无论是自发的还是由钉住控制作用引起的，并提供了局部和全局收敛的充分条件。我们允许使用主稳定函数方法来研究共同进化网络，从而获得几乎肯定的局部指数收敛条件，而全局条件则使用基于lyapunov的方法导出。然后利用理论结果在两个选择的应用程序中设计同步和固定控制协议。在第一种方法中，边缘动态被定制以诱导自发同步，而在第二种方法中，钉钉边缘被激活/停用，其权重被调制，以分布式方式驱动网络朝着钉钉器的轨迹移动。

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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来源期刊

Annual Reviews in Control 工程技术-自动化与控制系统

CiteScore

19.00

自引率

2.10%

发文量

审稿时长

36 days

期刊介绍： The field of Control is changing very fast now with technology-driven “societal grand challenges” and with the deployment of new digital technologies. The aim of Annual Reviews in Control is to provide comprehensive and visionary views of the field of Control, by publishing the following types of review articles: Survey Article: Review papers on main methodologies or technical advances adding considerable technical value to the state of the art. Note that papers which purely rely on mechanistic searches and lack comprehensive analysis providing a clear contribution to the field will be rejected. Vision Article: Cutting-edge and emerging topics with visionary perspective on the future of the field or how it will bridge multiple disciplines, and Tutorial research Article: Fundamental guides for future studies.