Huang Liang, Lai Ying-Cheng, Gatenby Robert A
Department of Electrical Engineering, Arizona State University, Tempe, Arizona 85287, USA.
Chaos. 2008 Mar;18(1):013101. doi: 10.1063/1.2826289.
There has been mounting evidence that many types of biological or technological networks possess a clustered structure. As many system functions depend on synchronization, it is important to investigate the synchronizability of complex clustered networks. Here we focus on one fundamental question: Under what condition can the network synchronizability be optimized? In particular, since the two basic parameters characterizing a complex clustered network are the probabilities of intercluster and intracluster connections, we investigate, in the corresponding two-dimensional parameter plane, regions where the network can be best synchronized. Our study yields a quite surprising finding: a complex clustered network is most synchronizable when the two probabilities match each other approximately. Mismatch, for instance caused by an overwhelming increase in the number of intracluster links, can counterintuitively suppress or even destroy synchronization, even though such an increase tends to reduce the average network distance. This phenomenon provides possible principles for optimal synchronization on complex clustered networks. We provide extensive numerical evidence and an analytic theory to establish the generality of this phenomenon.
越来越多的证据表明,许多类型的生物或技术网络具有聚类结构。由于许多系统功能依赖于同步,研究复杂聚类网络的同步性很重要。在这里,我们关注一个基本问题:在什么条件下网络同步性可以得到优化?特别是,由于表征复杂聚类网络的两个基本参数是簇间连接和簇内连接的概率,我们在相应的二维参数平面中研究网络能够实现最佳同步的区域。我们的研究得出了一个相当惊人的发现:当这两个概率大致相互匹配时,复杂聚类网络的同步性最佳。例如,由簇内链接数量的压倒性增加导致的不匹配,可能会违反直觉地抑制甚至破坏同步,尽管这种增加往往会缩短平均网络距离。这一现象为复杂聚类网络上的最佳同步提供了可能的原理。我们提供了大量的数值证据和一个解析理论来证实这一现象的普遍性。