Critical behaviour of the stochastic Wilson-Cowan model

Candia, A. de; Sarracino,; Apicella,; Arcangelis, L. de

doi:10.1101/2021.03.18.436022

Cited by 5 publications

(13 citation statements)

References 28 publications

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“…The distribution of avalanche sizes is found to scale as P(S) ∼ S −α , that of avalanche durations as P(T) ∼ T −τ , while the mean size of avalanches scales as �S� ∼ T γ as a function of the duration 4-8 . A good indicator of criticality is believed to be given by the scaling relation γ = τ −1 α−1 , as originally predicted in the theory of crackling noise 9,10 , as well as by the collapse of rescaled shapes of avalanches of different durations 4,7,8 . The simple branching model of avalanche propagation predicts exponents α = 3/2 , τ = 2 and γ = 2 , observed in some experimental realizations 1,11 and in models of neural dynamics, including the fully-connected stochastic Wilson-Cowan model 7 .…”

mentioning

confidence: 89%

“…In Ref. 7 it was shown that there is a critical point at h = 0 and w0,0 = β −1 α . For w0,0 larger than the critical value, an attractive fixed point with � 0 > 0 exists even when the external input h → 0 .…”

Section: The Modelmentioning

confidence: 99%

“…In Refs. 7,22,23 a further simplification was considered, that w ij depends only on the type of the pre-synaptic neuron, and is given by w ij = 1 2N E ( w0,0 + ws,0 ) if j is excitatory and w ij = 1 2N I ( w0,0 − ws,0 ) if j is inhibitory. In this case, the temporal autocorrelation function of time dependent variables, like the fraction of active neurons or the firing rate, can be written in the limit of large number of neurons as 23 where X(t) is the variable considered, X 0 is its average value in time, A 1 and A 2 are constant coefficients, and τ 1 , τ 2 are the characteristic relaxation times.…”

Section: The Modelmentioning

confidence: 99%

“…In the present paper we study the 2D version of the stochastic Wilson-Cowan model 7,22 , where neurons are distributed uniformly on a 2D lattice, and connections between them decay exponentially with the distance. We can tune the network topology from 2D to fully-connected by changing the ratio between the range of the exponential decay of the connections, and the side of the lattice L. While in the fully-connected case the dynamics of the model is completely described by specifying two variables, the fraction of active excitatory and inhibitory neurons, in the 2D case one needs to define such fractions at each site of the lattice.…”

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confidence: 99%

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

Apicella

Scarpetta

Arcangelis

et al. 2022

Sci Rep

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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, $$f^{-\beta }$$ f - β , with an exponent $$\beta $$ β close to 1 (pink noise). This exponent is predicted to be connected with the exponent $$\gamma $$ γ related to the scaling of the average size with the duration of avalanches of activity. “Mean field” models of neural dynamics predict exponents $$\beta $$ β and $$\gamma $$ γ 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 $$\beta $$ β and $$\gamma $$ γ markedly different from those of mean field, respectively around 1 and 1.3. The exponents $$\alpha $$ α and $$\tau $$ τ of avalanche size and duration distributions, equal to 1.5 and 2 in mean field, decrease respectively to $$1.29\pm 0.01$$ 1.29 ± 0.01 and $$1.37\pm 0.01$$ 1.37 ± 0.01 . This seems to suggest the possibility of a different universality class for the model in finite dimension.

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confidence: 89%

Section: The Modelmentioning

confidence: 99%

Section: The Modelmentioning

confidence: 99%

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confidence: 99%

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

Apicella

Scarpetta

Arcangelis

et al. 2022

Sci Rep

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“…The ambiguity intrinsic to stochastic extensions of ODE systems is not confined to ecological models. A series of papers have debated the most appropriate way to extend the deterministic Hodgkin-Huxley equations to incorporate the effects of random gating of ion channels in neural dynamics [3,14,20,21,28,30,31] At the level of large-scale neural circuits, several distinct stochastic generalizations have been proposed that coincide with the classical deterministic Wilson-Cowan neural field equations in the mean-field limit [5,6,9,12,13].…”

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confidence: 99%

Heteroclinic cycling and extinction in May-Leonard models with demographic stochasticity

Barendregt¹,

Thomas²

2021

Preprint

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May and Leonard (SIAM J. Appl. Math 1975) introduced a three-species Lotka-Volterra type population model that exhibits heteroclinic cycling. Rather than producing a periodic limit cycle, the trajectory takes longer and longer to complete each "cycle", passing closer and closer to unstable fixed points in which one population dominates and the others approach zero. Aperiodic heteroclinic dynamics have subsequently been studied in ecological systems (side-blotched lizards; colicinogenic E. coli), in the immune system, in neural information processing models ("winnerless competition"), and in models of neural central pattern generators. Yet as May and Leonard observed "Biologically, the behavior (produced by the model) is nonsense. Once it is conceded that the variables represent animals, and therefore cannot fall below unity, it is clear that the system will, after a few cycles, converge on some single population, extinguishing the other two." Here, we explore different ways of introducing discrete stochastic dynamics based on May and Leonard's ODE model, with application to ecological population dynamics, and to a neuromotor central pattern generator system. We study examples of several quantitatively distinct asymptotic behaviors, including total extinction of all species, extinction to a single species, and persistent cyclic dominance with finite mean cycle length.

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Heteroclinic cycling and extinction in May–Leonard models with demographic stochasticity

Barendregt

Thomas

2023

J. Math. Biol.

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May and Leonard (SIAM J Appl Math 29:243–253, 1975) introduced a three-species Lotka–Volterra type population model that exhibits heteroclinic cycling. Rather than producing a periodic limit cycle, the trajectory takes longer and longer to complete each “cycle”, passing closer and closer to unstable fixed points in which one population dominates and the others approach zero. Aperiodic heteroclinic dynamics have subsequently been studied in ecological systems (side-blotched lizards; colicinogenic Escherichia coli), in the immune system, in neural information processing models (“winnerless competition”), and in models of neural central pattern generators. Yet as May and Leonard observed “Biologically, the behavior (produced by the model) is nonsense. Once it is conceded that the variables represent animals, and therefore cannot fall below unity, it is clear that the system will, after a few cycles, converge on some single population, extinguishing the other two.” Here, we explore different ways of introducing discrete stochastic dynamics based on May and Leonard’s ODE model, with application to ecological population dynamics, and to a neuromotor central pattern generator system. We study examples of several quantitatively distinct asymptotic behaviors, including total extinction of all species, extinction to a single species, and persistent cyclic dominance with finite mean cycle length.

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Critical behaviour of the stochastic Wilson-Cowan model

Cited by 5 publications

References 28 publications

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

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

Heteroclinic cycling and extinction in May-Leonard models with demographic stochasticity

Heteroclinic cycling and extinction in May–Leonard models with demographic stochasticity

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