Add to ORKGFifty years ago, Wilson and Cowan developed a mathematical model to describe the activity of neural populations. In this seminal work, they divided the cells in three groups: active, sensitive and refractory, and obtained a dynamical system to describe the evolution of the average firing rates of the populations. In the present work, we investigate the impact of the often neglected refractory state and show that taking it into account can introduce new dynamics. Starting from a continuous-time Markov chain, we perform a rigorous derivation of a mean-field model that includes the refractory fractions of populations as dynamical variables. Then, we perform bifurcation analysis to explain the occurance of periodic solutions in cases where the ...
The Wilson-Cowan population model of neural activity has greatly influenced our understanding of the...
Abstract––The ideas of dynamical chaos have altered our understanding of the origin of random appear...
The neural dynamics generating sensory, motor, and cognitive functions are commonly understood throu...
We consider a simple Markovian class of the stochastic Wilson-Cowan type models of neuronal network ...
In this paper, we study the effect of two distinct discrete delays on the dynamics of a Wilson-Cowan...
International audienceIn this note, we clarify the well-posedness of the limit equations to the mean...
Oscillations arise in many real-world systems and are associated with both functional and dysfunctio...
The Wilson-Cowan model describes the evolution of excitatory and inhibitory activity in a synaptical...
We review the properties of a two population neuronal field model of the Wilson- Cowan type investig...
In this thesis methods from nonlinear dynamical systems, pattern formation and bifurcation theory, c...
In this paper we study the effect of two distinct discrete delays on the dynamics of a Wilson-Cowan ...
Neural dynamics is triggered by discrete synaptic inputs of finite amplitude. However, the neural re...
We present a mean-field formalism able to predict the collective dynamics of large networks of condu...
Low-dimensional yet rich dynamics often emerge in the brain. Examples include oscillations and chaot...
Neural computations arising from myriads of interactions between spiking neurons can be modeled as n...
The Wilson-Cowan population model of neural activity has greatly influenced our understanding of the...
Abstract––The ideas of dynamical chaos have altered our understanding of the origin of random appear...
The neural dynamics generating sensory, motor, and cognitive functions are commonly understood throu...
We consider a simple Markovian class of the stochastic Wilson-Cowan type models of neuronal network ...
In this paper, we study the effect of two distinct discrete delays on the dynamics of a Wilson-Cowan...
International audienceIn this note, we clarify the well-posedness of the limit equations to the mean...
Oscillations arise in many real-world systems and are associated with both functional and dysfunctio...
The Wilson-Cowan model describes the evolution of excitatory and inhibitory activity in a synaptical...
We review the properties of a two population neuronal field model of the Wilson- Cowan type investig...
In this thesis methods from nonlinear dynamical systems, pattern formation and bifurcation theory, c...
In this paper we study the effect of two distinct discrete delays on the dynamics of a Wilson-Cowan ...
Neural dynamics is triggered by discrete synaptic inputs of finite amplitude. However, the neural re...
We present a mean-field formalism able to predict the collective dynamics of large networks of condu...
Low-dimensional yet rich dynamics often emerge in the brain. Examples include oscillations and chaot...
Neural computations arising from myriads of interactions between spiking neurons can be modeled as n...
The Wilson-Cowan population model of neural activity has greatly influenced our understanding of the...
Abstract––The ideas of dynamical chaos have altered our understanding of the origin of random appear...
The neural dynamics generating sensory, motor, and cognitive functions are commonly understood throu...