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This study introduces a novel method to detect synchronized regions and collective behaviors in coupled dynamical systems using ordinal patterns and permutation entropy. The technique effectively identifies synchronization borders, even in complex, partially synchronized networks.

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Area of Science:

  • Complex Systems
  • Network Science
  • Dynamical Systems Theory

Background:

  • Identifying collective behaviors in coupled dynamical systems is crucial for understanding complex network dynamics.
  • Existing methods may struggle with partially synchronized states or networks with non-uniform connectivity.

Purpose of the Study:

  • To develop and validate a robust methodology for detecting synchronous regions and classifying collective behaviors in networks of coupled dynamical systems.
  • To extend the analysis to networks where traditional spatiotemporal analysis is infeasible.

Main Methods:

  • Utilizing ordinal patterns of spatial configurations of neighboring oscillators to detect synchronization at each time point.
  • Employing permutation entropy and forbidden sequence cardinality for the classification of collective behaviors.
  • Applying the method to a ring network of coupled logistic maps and subsequently to a network with random connections.

Main Results:

  • The method successfully detects synchronous regions and confirms previous findings on collective behavior identification.
  • It accurately identifies the boundaries of synchronous regions in partially synchronized networks.
  • Demonstrated efficacy on a randomly connected network, proving useful when spatiotemporal plots are not feasible.

Conclusions:

  • The proposed methodology offers a robust approach to analyzing synchronization and collective behaviors in complex networks.
  • It provides a powerful tool for characterizing network states, particularly in scenarios with partial synchronization or complex topologies.