Greenberg-Hastings dynamics on a small-world network: the collective extinct-active transition

Abstract

We present a numerical study of a reaction-diffusion model on a small-world network. We characterize the model's average activity FT after T time steps and the transition from a collective (global) extinct state to an active state in parameter space. We provide an explicit relation between the parameters of our model at the frontier between these states. A collective active state can be associated to a global epidemic spread, or to a persistent neuronal activity. We found that FT does not depends on disorder in the network if the transmission rate r or the average coordination number K are large enough. The collective extinct-active transition can be induced by changing two parameters associated to the network: K and the disorder parameter p (which controls the variance of K). We can also induce the transition by changing r, which controls the threshold size in the dynamics. In order to operate at the transition the parameters of the model must satisfy the relation rK=ap, where ap as a function of p/(1-p) is a stretched exponential function. Our results are relevant for systems that operate at the transition in order to increase its dynamic range and/or to operate under optimal information-processing conditions. We discuss how glassy behaviour appears within our model.