Properties of Zero-Lag Long-Range Synchronization via Dynamical Relaying

TL;DR

This paper investigates zero-lag long-range synchronization via dynamical relaying, revealing that antiphase relationships between intermediate and end systems enable in-phase synchronization, confirmed across various oscillator models.

Contribution

It provides a detailed analysis of the mechanisms behind dynamical relaying, demonstrating the role of antiphase synchronization in achieving zero-lag synchronization in different systems.

Findings

Antiphase synchronization between relay and end systems facilitates in-phase synchronization.

The phenomenon is consistent across quadratic maps, Kuramoto, and Rössler oscillators.

A simpler configuration also exhibits similar zero-lag synchronization features.

Abstract

In a recent letter, Fisher et al. reported the phenomenon of zero-lag long range isochronous synchronization via dynamical relaying in systems with delay [Phys. Rev. Lett. bf 97, 123902 (2006)]. They reported that when one has two coupled systems A and C, with delay between them, then the introduction of a third element B between A and C will allow them to synchronize even in regions of the parameter space where this was not possible without the presence of B. Here we study in detail the phenomenon and verify that in all the cases studied (including the ones reported by Fisher et al.) this occurs due to the tendency of A and B and B and C to be in antiphase synchronization and if A is in antiphase with B and B is in antiphase with C, it will imply that A and C are inphase. We show this in coupled quadratic maps, Kuramoto and R\"ossler oscillators. We also report that there is a simpler configuration where the same phenomenon occurs and has nearly the same features of the cases studied by Fisher et al.