Nonparametric estimation of the jump rate in mean field interacting systems of neurons

Abstract

We consider finite systems of N interacting neurons described by non-linear Hawkes processes in a mean field frame. Neurons are described by their membrane potential. They spike randomly, at a rate depending on their potential. In between successive spikes, their membrane potential follows a deterministic flow. We estimate the spiking rate function based on the observation of the system of N neurons over a fixed time interval [0,t]. Asymptotic are taken as N, the number of neurons, tends to infinity. We introduce a kernel estimator of Nadaraya-Watson type and discuss its asymptotic properties with help of the deterministic dynamical system describing the mean field limit. We compute the minimax rate of convergence in an L2 -error loss over a range of Hölder classes and obtain the classical rate of convergence N - 2β/ ( 2 β+ 1) , where β is the regularity of the unknown spiking rate function.