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Main Authors: Zhao, Na, Laing, Carlo R, Song, Jian, Liu, Shenquan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.03909
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author Zhao, Na
Laing, Carlo R
Song, Jian
Liu, Shenquan
author_facet Zhao, Na
Laing, Carlo R
Song, Jian
Liu, Shenquan
contents Stochastic resetting has shown promise in enhancing the stability of dynamical systems. Here, we apply this concept to theta neuron networks with partial resetting, where only a fraction of neurons is intermittently reset. We examine both infinite and finite reset rates, using the averaged firing rate as an indicator of network stability. At infinite reset rates, a high proportion of resetting neurons drives the network to stable rest or spiking states, collapsing the bistable region at the Cusp bifurcation and producing smooth transitions. Finite resetting introduces stochastic fluctuations, leading to complex dynamics that sometimes deviate from theoretical predictions. These insights highlight the role of partial resetting in stabilizing neural dynamics, with applications in biological systems and neuromorphic computing.
format Preprint
id arxiv_https___arxiv_org_abs_2412_03909
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Subsystem Resetting of a Heterogeneous Network of Theta Neurons
Zhao, Na
Laing, Carlo R
Song, Jian
Liu, Shenquan
Dynamical Systems
Stochastic resetting has shown promise in enhancing the stability of dynamical systems. Here, we apply this concept to theta neuron networks with partial resetting, where only a fraction of neurons is intermittently reset. We examine both infinite and finite reset rates, using the averaged firing rate as an indicator of network stability. At infinite reset rates, a high proportion of resetting neurons drives the network to stable rest or spiking states, collapsing the bistable region at the Cusp bifurcation and producing smooth transitions. Finite resetting introduces stochastic fluctuations, leading to complex dynamics that sometimes deviate from theoretical predictions. These insights highlight the role of partial resetting in stabilizing neural dynamics, with applications in biological systems and neuromorphic computing.
title Subsystem Resetting of a Heterogeneous Network of Theta Neurons
topic Dynamical Systems
url https://arxiv.org/abs/2412.03909