Network reconstruction based on evolutionary-game data via compressive sensing

Wen-Xu Wang; Ying-Cheng Lai; Celso Grebogi; Jieping Ye

doi:10.1103/PhysRevX.1.021021

Network reconstruction based on evolutionary-game data via compressive sensing

Wen-Xu Wang^*
, Ying-Cheng Lai
, Celso Grebogi
, Jieping Ye

^*Corresponding author for this work

Beijing Normal University
Arizona State University

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

163 Citations (Scopus)

Abstract

Evolutionary games model a common type of interactions in a variety of complex, networked, natural systems and social systems. Given such a system, uncovering the interacting structure of the underlying network is key to understanding its collective dynamics. Based on compressive sensing, we develop an efficient approach to reconstructing complex networks under game-based interactions from small amounts of data. The method is validated by using a variety of model networks and by conducting an actual experiment to reconstruct a social network. While most existing methods in this area assume oscillator networks that generate continuous-time data, our work successfully demonstrates that the extremely challenging problem of reverse engineering of complex networks can also be addressed even when the underlying dynamical processes are governed by realistic, evolutionary-game type of interactions in discrete time.

Original language	English
Article number	021021
Number of pages	7
Journal	Physical Review X
Volume	1
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevX.1.021021
Publication status	Published - 21 Dec 2011

Funding

We thank Dr. R. Yang, Dr. H.-X. Yang, and Dr. R.-R. Liu for valuable discussions. This work was supported by AFOSR under Grant No. FA9550-10-1-0083, by NSF under Grants No. CDI-1026710 and No. BECS-1023101, and by NSFC under Grant No. 11105011.

Keywords

scale-free networks
prisoners-dilemma game
social dilemmas
time-series
events
dynamics
cooperation
compressive sensing
network reconstruction

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abstract = "Evolutionary games model a common type of interactions in a variety of complex, networked, natural systems and social systems. Given such a system, uncovering the interacting structure of the underlying network is key to understanding its collective dynamics. Based on compressive sensing, we develop an efficient approach to reconstructing complex networks under game-based interactions from small amounts of data. The method is validated by using a variety of model networks and by conducting an actual experiment to reconstruct a social network. While most existing methods in this area assume oscillator networks that generate continuous-time data, our work successfully demonstrates that the extremely challenging problem of reverse engineering of complex networks can also be addressed even when the underlying dynamical processes are governed by realistic, evolutionary-game type of interactions in discrete time.",

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AU - Lai, Ying-Cheng

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N2 - Evolutionary games model a common type of interactions in a variety of complex, networked, natural systems and social systems. Given such a system, uncovering the interacting structure of the underlying network is key to understanding its collective dynamics. Based on compressive sensing, we develop an efficient approach to reconstructing complex networks under game-based interactions from small amounts of data. The method is validated by using a variety of model networks and by conducting an actual experiment to reconstruct a social network. While most existing methods in this area assume oscillator networks that generate continuous-time data, our work successfully demonstrates that the extremely challenging problem of reverse engineering of complex networks can also be addressed even when the underlying dynamical processes are governed by realistic, evolutionary-game type of interactions in discrete time.

AB - Evolutionary games model a common type of interactions in a variety of complex, networked, natural systems and social systems. Given such a system, uncovering the interacting structure of the underlying network is key to understanding its collective dynamics. Based on compressive sensing, we develop an efficient approach to reconstructing complex networks under game-based interactions from small amounts of data. The method is validated by using a variety of model networks and by conducting an actual experiment to reconstruct a social network. While most existing methods in this area assume oscillator networks that generate continuous-time data, our work successfully demonstrates that the extremely challenging problem of reverse engineering of complex networks can also be addressed even when the underlying dynamical processes are governed by realistic, evolutionary-game type of interactions in discrete time.

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KW - time-series

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Network reconstruction based on evolutionary-game data via compressive sensing

Abstract

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Keywords

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