Controlling extreme events on complex networks

Yu Zhong Chen; Zi Gang Huang; Ying-Cheng Lai

doi:10.1038/srep06121

Controlling extreme events on complex networks

Yu Zhong Chen, Zi Gang Huang, Ying-Cheng Lai

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

Extreme events, a type of collective behavior in complex networked dynamical systems, often can have catastrophic consequences. To develop effective strategies to control extreme events is of fundamental importance and practical interest. Utilizing transportation dynamics on complex networks as a prototypical setting, we find that making the network "mobile" can effectively suppress extreme events. A striking, resonance-like phenomenon is uncovered, where an optimal degree of mobility exists for which the probability of extreme events is minimized. We derive an analytic theory to understand the mechanism of control at a detailed and quantitative level, and validate the theory numerically. Implications of our finding to current areas such as cybersecurity are discussed.

Original language	English (US)
Article number	6121
Journal	Scientific reports
Volume	4
DOIs	https://doi.org/10.1038/srep06121
State	Published - Aug 18 2014

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title = "Controlling extreme events on complex networks",

abstract = "Extreme events, a type of collective behavior in complex networked dynamical systems, often can have catastrophic consequences. To develop effective strategies to control extreme events is of fundamental importance and practical interest. Utilizing transportation dynamics on complex networks as a prototypical setting, we find that making the network {"}mobile{"} can effectively suppress extreme events. A striking, resonance-like phenomenon is uncovered, where an optimal degree of mobility exists for which the probability of extreme events is minimized. We derive an analytic theory to understand the mechanism of control at a detailed and quantitative level, and validate the theory numerically. Implications of our finding to current areas such as cybersecurity are discussed.",

author = "Chen, {Yu Zhong} and Huang, {Zi Gang} and Ying-Cheng Lai",

note = "Funding Information: We thank Prof. W.-X. Wang and Prof. L. Huang for helpful discussions. This work was partially supported by AFOSR under Grant No. FA9550-10-1-0083, by NSF under Grant No. CDI-1026710 and by ARO under Grant No. W911NF-14-1-0504.",

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doi = "10.1038/srep06121",

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AU - Chen, Yu Zhong

AU - Huang, Zi Gang

AU - Lai, Ying-Cheng

N1 - Funding Information: We thank Prof. W.-X. Wang and Prof. L. Huang for helpful discussions. This work was partially supported by AFOSR under Grant No. FA9550-10-1-0083, by NSF under Grant No. CDI-1026710 and by ARO under Grant No. W911NF-14-1-0504.

PY - 2014/8/18

Y1 - 2014/8/18

N2 - Extreme events, a type of collective behavior in complex networked dynamical systems, often can have catastrophic consequences. To develop effective strategies to control extreme events is of fundamental importance and practical interest. Utilizing transportation dynamics on complex networks as a prototypical setting, we find that making the network "mobile" can effectively suppress extreme events. A striking, resonance-like phenomenon is uncovered, where an optimal degree of mobility exists for which the probability of extreme events is minimized. We derive an analytic theory to understand the mechanism of control at a detailed and quantitative level, and validate the theory numerically. Implications of our finding to current areas such as cybersecurity are discussed.

AB - Extreme events, a type of collective behavior in complex networked dynamical systems, often can have catastrophic consequences. To develop effective strategies to control extreme events is of fundamental importance and practical interest. Utilizing transportation dynamics on complex networks as a prototypical setting, we find that making the network "mobile" can effectively suppress extreme events. A striking, resonance-like phenomenon is uncovered, where an optimal degree of mobility exists for which the probability of extreme events is minimized. We derive an analytic theory to understand the mechanism of control at a detailed and quantitative level, and validate the theory numerically. Implications of our finding to current areas such as cybersecurity are discussed.

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Controlling extreme events on complex networks

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