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Stochastic Spiking-Bursting Excitability and Transition to Chaos in a Discrete-Time Neuron Model

Irina Bashkirtseva, Venera Nasyrova, Lev Ryashko

2020International Journal of Bifurcation and Chaos17 citationsDOI

Abstract

The randomly forced Rulkov neuron model with the discontinuous 2D-map is considered. We study the phenomena of the stochastic excitement: (i) noise-induced spiking in the parametric zone where the equilibrium is a single attractor; (ii) stochastic generation of the spiking in bistability zone; (iii) noise-induced bursting in the parametric zone where the deterministic model exhibits the tonic spiking. These stochastic effects are investigated numerically by means of probability density functions and mean values of interspike (interburst) intervals. For the parametric study of these noise-induced transformations, we suggest an analytical approach taking into account the stochastic sensitivity of attractors and peculiarities of deterministic phase portraits. In this analysis, we study the mutual arrangement of confidence domains and superthreshold zones near deterministic attractors. This approach gives a prediction of the onset of the noise-induced excitement in the form of the transitions quiescence-spiking or spiking-bursting. A relationship of these phenomena with the order-chaos transformations are discussed.

Topics & Concepts

BurstingAttractorBistabilityStatistical physicsParametric statisticsPhase portraitNoise (video)Biological neuron modelStochastic modellingFirst-hitting-time modelMathematicsStochastic processNonlinear systemPhysicsBifurcationComputer scienceMathematical analysisStatisticsArtificial intelligenceArtificial neural networkQuantum mechanicsNeuroscienceImage (mathematics)Biologystochastic dynamics and bifurcationNeural dynamics and brain functionNonlinear Dynamics and Pattern Formation
Stochastic Spiking-Bursting Excitability and Transition to Chaos in a Discrete-Time Neuron Model | Litcius