Synchronization in starlike networks of phase oscillators

Can Xu; Jian Gao; Stefano Boccaletti; Zhigang Zheng; Shuguang Guan

doi:10.1103/PhysRevE.100.012212

Synchronization in starlike networks of phase oscillators

Can Xu
, Jian Gao
, Stefano Boccaletti
, Zhigang Zheng
, Shuguang Guan

School of Physics and Electronic Science

Huaqiao University
University of Groningen
National Research Council of Italy
Northwestern Polytechnical University Xian

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

24 Scopus citations

Abstract

We fully describe the mechanisms underlying synchronization in starlike networks of phase oscillators. In particular, the routes to synchronization and the critical points for the associated phase transitions are determined analytically. In contrast to the classical Kuramoto theory, we unveil that relaxation rates to each equilibrium state indeed exist and remain invariant under three levels of descriptions corresponding to different geometric implications. The special symmetry in the coupling determines a quasi-Hamiltonian property, which is further unveiled on the basis of singular perturbation theory. Since starlike coupling configurations constitute the building blocks of technological and biological real world networks, our paper paves the way towards the understanding of the functioning of such real world systems in many practical situations.

Original language	English
Article number	012212
Journal	Physical Review E
Volume	100
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevE.100.012212
State	Published - 23 Jul 2019

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10.1103/PhysRevE.100.012212

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title = "Synchronization in starlike networks of phase oscillators",

abstract = "We fully describe the mechanisms underlying synchronization in starlike networks of phase oscillators. In particular, the routes to synchronization and the critical points for the associated phase transitions are determined analytically. In contrast to the classical Kuramoto theory, we unveil that relaxation rates to each equilibrium state indeed exist and remain invariant under three levels of descriptions corresponding to different geometric implications. The special symmetry in the coupling determines a quasi-Hamiltonian property, which is further unveiled on the basis of singular perturbation theory. Since starlike coupling configurations constitute the building blocks of technological and biological real world networks, our paper paves the way towards the understanding of the functioning of such real world systems in many practical situations.",

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AU - Xu, Can

AU - Gao, Jian

AU - Boccaletti, Stefano

AU - Zheng, Zhigang

AU - Guan, Shuguang

PY - 2019/7/23

Y1 - 2019/7/23

N2 - We fully describe the mechanisms underlying synchronization in starlike networks of phase oscillators. In particular, the routes to synchronization and the critical points for the associated phase transitions are determined analytically. In contrast to the classical Kuramoto theory, we unveil that relaxation rates to each equilibrium state indeed exist and remain invariant under three levels of descriptions corresponding to different geometric implications. The special symmetry in the coupling determines a quasi-Hamiltonian property, which is further unveiled on the basis of singular perturbation theory. Since starlike coupling configurations constitute the building blocks of technological and biological real world networks, our paper paves the way towards the understanding of the functioning of such real world systems in many practical situations.

AB - We fully describe the mechanisms underlying synchronization in starlike networks of phase oscillators. In particular, the routes to synchronization and the critical points for the associated phase transitions are determined analytically. In contrast to the classical Kuramoto theory, we unveil that relaxation rates to each equilibrium state indeed exist and remain invariant under three levels of descriptions corresponding to different geometric implications. The special symmetry in the coupling determines a quasi-Hamiltonian property, which is further unveiled on the basis of singular perturbation theory. Since starlike coupling configurations constitute the building blocks of technological and biological real world networks, our paper paves the way towards the understanding of the functioning of such real world systems in many practical situations.

UR - https://www.scopus.com/pages/publications/85071969585

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Synchronization in starlike networks of phase oscillators

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