Ralf Toenjes, Naoki Masuda, Hiroshi Kori
Published 2010-03-10, updated 2010-08-02Version 2
We numerically study a directed small-world network consisting of attractively coupled, identical phase oscillators. While complete synchronization is always stable, it is not always reachable from random initial conditions. Depending on the shortcut density and on the asymmetry of the phase coupling function, there exists a regime of persistent chaotic dynamics. By increasing the density of shortcuts or decreasing the asymmetry of the phase coupling function, we observe a discontinuous transition in the ability of the system to synchronize. Using a control technique, we identify the bifurcation scenario of the order parameter. We also discuss the relation between dynamics and topology and remark on the similarity of the synchronization transition to directed percolation.
Comments: This article has been accepted in AIP, Chaos. After it is published, it will be found at http://chaos.aip.org/, 12 pages, 9 figures, 1 table
Journal: Chaos 20, 033108 (2010)
Synchronization Transition in the Kuramoto Model with Colored Noise
Majority-vote on directed Small-World networks
Optimal reinforcement learning near the edge of synchronization transition
![QR code for arXiv:1003.2020 [cond-mat.dis-nn]](http://oss.arxitics.com/images/favicon.svg)