Stability and synchronization of complex networks composed of dynamical nodes with discontinuities

由不连续动态节点组成的复杂网络的稳定性和同步性

• 批准号: RGPIN-2016-04134
• 负责人: Liu, Xinzhi
• 金额: $ 1.31万
• 依托单位: University of Waterloo
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=614858
• 关键词: Stability; synchronization; complex; networks; composed

With the rapid development of communication, computation and the Internet, which allow us to gather and analyze large amount of information, there has been a growing interest in complex networks in recent years. A complex network is a large set of interconnected dynamical units called nodes. Each node is a dynamical system with specific behavior. There are numerous examples of natural and man made complex networks such as genetic regulatory networks, communication networks, transportation networks, electrical power grids, social relation networks, and the World Wide Web, among many others. A complex network can exhibit complicated dynamics that may be totally different from those of a single node due to its coupling architecture. Thus it is very important to study the collective dynamical behavior, such as stability and synchronization, of complex dynamical networks as well as properties of other relevant processes that take place in complex networks such as the spreading of diseases and information. In this research program, we will mainly focus on those complex networks composed of dynamical units with switching or jump discontinuities. Such dynamical units include switched systems, impulsive systems, or more generally hybrid systems, which are often used to model practical systems having certain embedded intelligence (sometime called the smart systems). Our objectives include: (i) to develop stability theory and robustness of such complex networks;(ii) to establish various synchronization criteria of complex networks; (iii) to develop effective impulsive control and hybrid control methods for stabilization and synchronization of complex networks; (iv) to develop efficient and reliable computational algorithms for computational modeling and simulation of complex networks; (v) to apply the obtained methods to practical problems such as disease transmission and spreading over social networks. The outcomes of this research program will result in new stability and robustness results, new synchronization criteria, effective impulsive and hybrid control methods, efficient computational algorithms for modeling and simulation of complex dynamical networks. The outcomes will enhance Canada's reputation for leading edge research and facilitate opportunities for international collaboration. We expect to publish several top quality papers per year in prestigious international journals. This research program will also provide an excellent opportunity for training graduate students and other highly qualified personnel.

近年来，随着通信、计算和互联网的迅速发展，人们可以收集和分析大量的信息，对复杂网络的研究越来越受到人们的关注。一个复杂的网络是一个大型的相互连接的动态单元称为节点。每个节点都是一个 具有特定行为的动力系统。有许多自然和人造复杂网络的例子，如遗传调控网络， 通信网络、运输网络、电网、社会关系网络和万维网等。一 复杂网络由于其耦合结构，可以表现出与单个节点完全不同的复杂动力学特性。具有十分 这对于研究复杂动力网络的集体动力学行为，如稳定性和同步以及其他网络的性质非常重要。 在复杂网络中发生的相关过程，如疾病和信息的传播。 在本研究计划中，我们将主要关注那些由具有切换或跳跃不连续性的动态单元组成的复杂网络。等 动态单元包括切换系统、脉冲系统或更一般的混合系统，它们通常用于对实际系统进行建模 具有一定的嵌入式智能（有时称为智能系统）。我们的目标包括：（i）发展稳定性理论和鲁棒性， 复杂网络;（ii）建立复杂网络的各种同步准则;（iii）发展有效的脉冲控制和混合控制 复杂网络的稳定和同步方法;（iv）开发用于复杂网络的计算建模和仿真的高效可靠的计算算法;（v）将所获得的方法应用于实际问题，例如疾病在社交网络上的传播和传播。 该研究计划的成果将导致新的稳定性和鲁棒性结果，新的同步准则，有效的脉冲和混合 控制方法，用于复杂动态网络建模和仿真的高效计算算法。 这些成果将提高加拿大在前沿研究方面的声誉，并促进国际合作的机会。我们希望每年在著名的国际期刊上发表几篇高质量的论文。这项研究计划还将为培养研究生和其他高素质人才提供一个极好的机会。