Saved in:
Bibliographic Details
Main Authors: Shashangan, R., Sudharsan, S., Ghosh, Dibakar, Senthilvelan, M.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.12753
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915403544920064
author Shashangan, R.
Sudharsan, S.
Ghosh, Dibakar
Senthilvelan, M.
author_facet Shashangan, R.
Sudharsan, S.
Ghosh, Dibakar
Senthilvelan, M.
contents In previous studies, the propagation of extreme events across nodes in monolayer networks has been extensively studied. In this work, we extend this investigation to explore the propagation of extreme events between two distinct layers in a multiplex network. We consider a two-layer network, where one layer is globally coupled and exhibits extreme events, while the second layer remains uncoupled. The interlayer connections between the layers are either unidirectional or bidirectional. We find that unidirectional coupling between the layers can induce extreme events in the uncoupled layer, whereas bidirectional coupling tends to mitigate extreme events in the globally coupled layer. To characterize extreme and non-extreme states, we use probability plots to identify distinct regions in the parameter space. Additionally, we study the robustness of extreme events emergence by examining various network topologies in the uncoupled layer. The mechanism behind the occurrence of extreme events is explored, with a particular focus on the transition from asynchronous states to a fully synchronized excitable state. For numerical simulations, we use nonidentical FitzHugh-Nagumo neurons at each node, which captures the dynamical behavior of both coupled and uncoupled layers. Our findings suggest that extreme events in the uncoupled layer emerge through the gradual disappearance of disorder, accompanied by occasional bursts of synchronized activity. Results obtained in this work will serve a starting point in understanding the dynamics behind the propagation of extreme events in real-world networks.
format Preprint
id arxiv_https___arxiv_org_abs_2501_12753
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Propagation of extreme events in multiplex neuronal networks
Shashangan, R.
Sudharsan, S.
Ghosh, Dibakar
Senthilvelan, M.
Chaotic Dynamics
In previous studies, the propagation of extreme events across nodes in monolayer networks has been extensively studied. In this work, we extend this investigation to explore the propagation of extreme events between two distinct layers in a multiplex network. We consider a two-layer network, where one layer is globally coupled and exhibits extreme events, while the second layer remains uncoupled. The interlayer connections between the layers are either unidirectional or bidirectional. We find that unidirectional coupling between the layers can induce extreme events in the uncoupled layer, whereas bidirectional coupling tends to mitigate extreme events in the globally coupled layer. To characterize extreme and non-extreme states, we use probability plots to identify distinct regions in the parameter space. Additionally, we study the robustness of extreme events emergence by examining various network topologies in the uncoupled layer. The mechanism behind the occurrence of extreme events is explored, with a particular focus on the transition from asynchronous states to a fully synchronized excitable state. For numerical simulations, we use nonidentical FitzHugh-Nagumo neurons at each node, which captures the dynamical behavior of both coupled and uncoupled layers. Our findings suggest that extreme events in the uncoupled layer emerge through the gradual disappearance of disorder, accompanied by occasional bursts of synchronized activity. Results obtained in this work will serve a starting point in understanding the dynamics behind the propagation of extreme events in real-world networks.
title Propagation of extreme events in multiplex neuronal networks
topic Chaotic Dynamics
url https://arxiv.org/abs/2501.12753