Litcius/Paper detail

Power spectrum and critical exponents in the 2D stochastic Wilson–Cowan model

Ilenia Apicella, Silvia Scarpetta, L. de Arcangelis, Alessandro Sarracino, A. de Candia

2022Scientific Reports20 citationsDOIOpen Access PDF

Abstract

The power spectrum of brain activity is composed by peaks at characteristic frequencies superimposed to a background that decays as a power law of the frequency, [Formula: see text], with an exponent [Formula: see text] close to 1 (pink noise). This exponent is predicted to be connected with the exponent [Formula: see text] related to the scaling of the average size with the duration of avalanches of activity. "Mean field" models of neural dynamics predict exponents [Formula: see text] and [Formula: see text] equal or near 2 at criticality (brown noise), including the simple branching model and the fully-connected stochastic Wilson-Cowan model. We here show that a 2D version of the stochastic Wilson-Cowan model, where neuron connections decay exponentially with the distance, is characterized by exponents [Formula: see text] and [Formula: see text] markedly different from those of mean field, respectively around 1 and 1.3. The exponents [Formula: see text] and [Formula: see text] of avalanche size and duration distributions, equal to 1.5 and 2 in mean field, decrease respectively to [Formula: see text] and [Formula: see text]. This seems to suggest the possibility of a different universality class for the model in finite dimension.

Topics & Concepts

ExponentUniversality (dynamical systems)Renormalization groupScalingMean field theoryCritical exponentStatistical physicsPhysicsPower lawMathematicsMathematical physicsCombinatoricsQuantum mechanicsStatisticsGeometryLinguisticsPhilosophyNeural dynamics and brain functionstochastic dynamics and bifurcationFunctional Brain Connectivity Studies