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Universal driving structure of self-sustained oscillatory complex networks

Recently, self-sustained oscillations in complex networks consisting of nonoscillatory nodes (network oscillators) have attracted great interest in diverse natural and social fields. Due to complexity of network behaviors, little is known so far about the basic structures and fundamental rules underlying the oscillations, not to mention the principles of how to control it. In this article we propose a common design principle for oscillations; predict novel and universal Branched Circle (BC) structures of oscillatory networks based on this principle; and suggest an operable Complexity Reduction Method to reveal the BC structures. These ideas are applied to excitable cell networks (including neural cell networks), and genomic regulatory networks. Universal BC structures are identified clearly in these two considerably different systems. These BC structures reveal for the first time both oscillation sources and wave propagation pathways of complex networks, and guide us to control the oscillations with surprisingly high efficiency.

preprint2011arXivOpen access
Xuhong LiaoWeiming YeXiaodong HuangQinzhi XiaXuhui HuangPengfei LiYu QianXiaoqing HuangGang Hu
nlin.AO
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Open access9 authors1 topic
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Xuhong LiaoWeiming YeXiaodong HuangQinzhi XiaXuhui HuangPengfei LiYu QianXiaoqing HuangGang Hu

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