Desynchronization by phase slip patterns in networks of pulse-coupled oscillators with delays: Desynchronization by phase slip patterns

Vladimir Klinshov; Leonhard Lücken; Serhiy Yanchuk

doi:10.1140/epjst/e2018-800073-7

Desynchronization by phase slip patterns in networks of pulse-coupled oscillators with delays: Desynchronization by phase slip patterns

Vladimir Klinshov
, Leonhard Lücken
, Serhiy Yanchuk

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

Abstract

Coupling delays may cause drastic changes in the dynamics of oscillatory networks. In the present paper we investigate how coupling delays alter synchronization processes in networks of all-to-all coupled pulse oscillators. We derive an analytic criterion for the stability of synchrony and study the synchronization areas in the space of the delay and coupling strength. Specific attention is paid to the scenario of destabilization on the borders of the synchronization area. We show that in bifurcation points the system possesses homoclinic loops, which give rise to complex long- or quasi-periodic solutions. These newly born solutions are characterized by a synchronous group, from which an oscillator periodically escapes, laps one period, and rejoins. We call such a dynamical regime “phase slip patterns”.

Original language	English
Pages (from-to)	1117-1128
Number of pages	12
Journal	European Physical Journal: Special Topics
Volume	227
Issue number	10-11
DOIs	https://doi.org/10.1140/epjst/e2018-800073-7
Publication status	Published - 1 Nov 2018
Externally published	Yes

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title = "Desynchronization by phase slip patterns in networks of pulse-coupled oscillators with delays: Desynchronization by phase slip patterns",

abstract = "Coupling delays may cause drastic changes in the dynamics of oscillatory networks. In the present paper we investigate how coupling delays alter synchronization processes in networks of all-to-all coupled pulse oscillators. We derive an analytic criterion for the stability of synchrony and study the synchronization areas in the space of the delay and coupling strength. Specific attention is paid to the scenario of destabilization on the borders of the synchronization area. We show that in bifurcation points the system possesses homoclinic loops, which give rise to complex long- or quasi-periodic solutions. These newly born solutions are characterized by a synchronous group, from which an oscillator periodically escapes, laps one period, and rejoins. We call such a dynamical regime “phase slip patterns”.",

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AU - Klinshov, Vladimir

AU - Lücken, Leonhard

AU - Yanchuk, Serhiy

PY - 2018/11/1

Y1 - 2018/11/1

N2 - Coupling delays may cause drastic changes in the dynamics of oscillatory networks. In the present paper we investigate how coupling delays alter synchronization processes in networks of all-to-all coupled pulse oscillators. We derive an analytic criterion for the stability of synchrony and study the synchronization areas in the space of the delay and coupling strength. Specific attention is paid to the scenario of destabilization on the borders of the synchronization area. We show that in bifurcation points the system possesses homoclinic loops, which give rise to complex long- or quasi-periodic solutions. These newly born solutions are characterized by a synchronous group, from which an oscillator periodically escapes, laps one period, and rejoins. We call such a dynamical regime “phase slip patterns”.

AB - Coupling delays may cause drastic changes in the dynamics of oscillatory networks. In the present paper we investigate how coupling delays alter synchronization processes in networks of all-to-all coupled pulse oscillators. We derive an analytic criterion for the stability of synchrony and study the synchronization areas in the space of the delay and coupling strength. Specific attention is paid to the scenario of destabilization on the borders of the synchronization area. We show that in bifurcation points the system possesses homoclinic loops, which give rise to complex long- or quasi-periodic solutions. These newly born solutions are characterized by a synchronous group, from which an oscillator periodically escapes, laps one period, and rejoins. We call such a dynamical regime “phase slip patterns”.

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JO - European Physical Journal: Special Topics

JF - European Physical Journal: Special Topics

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ER -

Desynchronization by phase slip patterns in networks of pulse-coupled oscillators with delays: Desynchronization by phase slip patterns

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