1. Explosive synchronization in populations of cooperative and competitive oscillators.
- Author
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Dai, Xiangfeng, Li, Xuelong, Gutiérrez, Ricardo, Guo, Hao, Jia, Danyang, Perc, Matjaž, Manshour, Pouya, Wang, Zhen, and Boccaletti, Stefano
- Subjects
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SYNCHRONIZATION , *NERVE tissue , *MOLECULAR graphs , *EXPLOSIVES , *HEART diseases , *HYSTERESIS - Abstract
• We consider a population fragmented into cooperative and competitive units, i.e. we account explicitly for the two fundamental adaptation mechanisms at the basis of dynamical competition and cooperation (or interdependence) in networks. • Not only we reveal that the type of transition can in fact be controlled simply by adapting the balance between the two oscillator types. • We examine the role of different graph's mesoscales in the feedback leading to adaption, we show that the irreversibility associated to ES is actually enhanced when the adaptation mechanisms span larger scales. Synchronization is a subject of interdisciplinary relevance, interpolating between efficiency in transportation and digital data transfers to disease in cardiac and neural tissue. While continuous transitions to synchronization are gradual and easy to control, explosive transitions may occur suddenly and can have catastrophic effects. Here we report that in populations of cooperative and competitive oscillators the transition can be tuned between continuous and explosive simply by adjusting the balance between the two oscillator types. We show that this phenomenon is independent of the network topology, and can be described analytically already in the mean-field approximation. Moreover, we provide evidence that the difference between the two transitions is due to a merging process of clusters which is forbidden by adaptation, and that the hysteresis associated to the explosive transition is enhanced when the adaptive mechanisms span larger scales. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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