Open AccessAnalytical investigation of self-organized criticality in neural networks
Author(s) -
Felix Droste,
Anne-Ly Do,
Thilo Groß
Publication year - 2012
Publication title -
journal of the royal society interface
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.655
H-Index - 139
eISSN - 1742-5689
pISSN - 1742-5662
DOI - 10.1098/rsif.2012.0558
Subject(s) - criticality , self organized criticality , homeostatic plasticity , statistical physics , computer science , dynamical systems theory , representation (politics) , bifurcation , artificial neural network , dynamical system (definition) , physics , topology (electrical circuits) , mathematics , artificial intelligence , synaptic plasticity , biology , metaplasticity , nonlinear system , quantum mechanics , biochemistry , receptor , combinatorics , politics , political science , nuclear physics , law
Dynamical criticality has been shown to enhance information processing in dynamical systems, and there is evidence for self-organized criticality in neural networks. A plausible mechanism for such self-organization is activity-dependent synaptic plasticity. Here, we model neurons as discrete-state nodes on an adaptive network following stochastic dynamics. At a threshold connectivity, this system undergoes a dynamical phase transition at which persistent activity sets in. In a low-dimensional representation of the macroscopic dynamics, this corresponds to a transcritical bifurcation. We show analytically that adding activity-dependent rewiring rules, inspired by homeostatic plasticity, leads to the emergence of an attractive steady state at criticality and present numerical evidence for the system's evolution to such a state.
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