Spike-Phase Coupling As an Order Parameter in a Leaky Integrate-and-Fire Model

Abstract

While criticality is widely observed in neural networks, its underlying neural mechanism is not known well. We consider a network of N excitatory leaky integrated and fire (LIF) neurons that reside on a regular lattice with periodic boundary conditions. The cooperation between neurons, K, plays the role of the control parameter that is expected to generate criticality when the critical cooperation strength, Kc, is adopted. We show that the coupling between spike timing and the phase of temporal fluctuations of a cooperative activity of the network, i.e. population-averaged voltage (PAV), resorts to identifying an order parameter. By increasing K, we find a continuous transition from irregular spiking to a phase-locked state at the critical point, Kc. Moreover, we deploy the finite-size scaling analysis to obtain the critical exponents of this transition. We also show that the neuronal avalanches created at this critical point, display a remarkable scaling behavior with the exponents in a fair agreement with the experimental values.