Mean field approximation of two coupled populations of excitable units

The analysis on stability and bifurcations in the macroscopic dynamics exhibited by the system of two coupled large populations comprised of \(N\) stochastic excitable units each is performed by studying an approximate system, obtained by replacing each population with the corresponding mean-field m...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2012-09
Main Authors: Franovic, I, Todorovic, K, Vasovic, N, Buric, N
Format: Article
Language:English
Subjects:
Bifurcations
Bistability
Communication
Couplings
Delay
Differential equations
Domains
Dynamic stability
Mathematical models
Parameters
Populations
Stability analysis
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The analysis on stability and bifurcations in the macroscopic dynamics exhibited by the system of two coupled large populations comprised of \(N\) stochastic excitable units each is performed by studying an approximate system, obtained by replacing each population with the corresponding mean-field model. In the exact system, one has the units within an ensemble communicating via the time-delayed linear couplings, whereas the inter-ensemble terms involve the nonlinear time-delayed interaction mediated by the appropriate global variables. The aim is to demonstrate that the bifurcations affecting the stability of the stationary state of the original system, governed by a set of 4N stochastic delay-differential equations for the microscopic dynamics, can accurately be reproduced by a flow containing just four deterministic delay-differential equations which describe the evolution of the mean-field based variables. In particular, the considered issues include determining the parameter domains where the stationary state is stable, the scenarios for the onset and the time-delay induced suppression of the collective mode, as well as the parameter domains admitting bistability between the equilibrium and the oscillatory state. We show how analytically tractable bifurcations occurring in the approximate model can be used to identify the characteristic mechanisms by which the stationary state is destabilized under different system configurations, like those with symmetrical or asymmetrical inter-population couplings.
ISSN:2331-8422
DOI:10.48550/arxiv.1209.0073