Distinguishing Direct from Indirect Interactions in Oscillatory Networks with Multiple Time Scales

Jakob Nawrath; M. Carmen Romano; Marco Thiel; Istvan Z. Kiss; Mahesh Wickramasinghe; Jens Timmer; Juergen Kurths; Bjoern Schelter

doi:10.1103/PhysRevLett.104.038701

Distinguishing Direct from Indirect Interactions in Oscillatory Networks with Multiple Time Scales

Jakob Nawrath, M. Carmen Romano, Marco Thiel, Istvan Z. Kiss, Mahesh Wickramasinghe, Jens Timmer, Juergen Kurths, Bjoern Schelter

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Abstract

We propose a method to infer the coupling structure in networks of nonlinear oscillatory systems with multiple time scales. The method of partial phase synchronization allows us to infer the coupling structure for coupled nonlinear oscillators with one well-defined time scale. The case of oscillators with multiple time scales has remained a challenge until now. Here, we introduce partial recurrence based synchronization analysis to tackle this challenge. We successfully apply the proposed method to model systems and experimental data from coupled electrochemical oscillators. The statistical significance of the results is evaluated based on a surrogate hypothesis test.

Original language	English
Article number	038701
Number of pages	4
Journal	Physical Review Letters
Volume	104
Issue number	3
Early online date	21 Jan 2010
DOIs	https://doi.org/10.1103/PhysRevLett.104.038701
Publication status	Published - 22 Jan 2010

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10.1103/PhysRevLett.104.038701

Nawrath PRL10
© 2010 The American Physical Society 10.1103/PhysRevLett.104.038701
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Brainatics: prediction, detection and monitoring of Epilepsy
Bjoern Schelter (Coordinator) & Marco Thiel (Coordinator)
Impact: Health and Wellbeing

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abstract = "We propose a method to infer the coupling structure in networks of nonlinear oscillatory systems with multiple time scales. The method of partial phase synchronization allows us to infer the coupling structure for coupled nonlinear oscillators with one well-defined time scale. The case of oscillators with multiple time scales has remained a challenge until now. Here, we introduce partial recurrence based synchronization analysis to tackle this challenge. We successfully apply the proposed method to model systems and experimental data from coupled electrochemical oscillators. The statistical significance of the results is evaluated based on a surrogate hypothesis test.",

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AU - Wickramasinghe, Mahesh

AU - Timmer, Jens

AU - Kurths, Juergen

AU - Schelter, Bjoern

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AB - We propose a method to infer the coupling structure in networks of nonlinear oscillatory systems with multiple time scales. The method of partial phase synchronization allows us to infer the coupling structure for coupled nonlinear oscillators with one well-defined time scale. The case of oscillators with multiple time scales has remained a challenge until now. Here, we introduce partial recurrence based synchronization analysis to tackle this challenge. We successfully apply the proposed method to model systems and experimental data from coupled electrochemical oscillators. The statistical significance of the results is evaluated based on a surrogate hypothesis test.

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Distinguishing Direct from Indirect Interactions in Oscillatory Networks with Multiple Time Scales

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