Litcius/Paper detail

Neuronal synchronization in long-range time-varying networks

Sarbendu Rakshit, Soumen Majhi, Jürgen Kurths, Dibakar Ghosh

2021Chaos An Interdisciplinary Journal of Nonlinear Science36 citationsDOI

Abstract

We study synchronization in neuronal ensembles subject to long-range electrical gap junctions which are time-varying. As a representative example, we consider Hindmarsh–Rose neurons interacting based upon temporal long-range connections through electrical couplings. In particular, we adopt the connections associated with the direct 1-path network to form a small-world network and follow-up with the corresponding long-range network. Further, the underlying direct small-world network is allowed to temporally change; hence, all long-range connections are also temporal, which makes the model much more realistic from the neurological perspective. This time-varying long-range network is formed by rewiring each link of the underlying 1-path network stochastically with a characteristic rewiring probability pr, and accordingly all indirect k(>1)-path networks become temporal. The critical interaction strength to reach complete neuronal synchrony is much lower when we take up rapidly switching long-range interactions. We employ the master stability function formalism in order to characterize the local stability of the state of synchronization. The analytically derived stability condition for the complete synchrony state agrees well with the numerical results. Our work strengthens the understanding of time-varying long-range interactions in neuronal ensembles.

Topics & Concepts

Synchronization (alternating current)Range (aeronautics)Complex networkStability (learning theory)Computer scienceNetwork modelTopology (electrical circuits)Statistical physicsPhysicsMathematicsArtificial intelligenceEngineeringMachine learningCombinatoricsAerospace engineeringWorld Wide WebNeural dynamics and brain functionstochastic dynamics and bifurcationNonlinear Dynamics and Pattern Formation