Memory Storage and Retrieval in Sparsely Connected Balanced Networks (2305.07656v1)

Abstract: Ever since the last two decades of the past century pioneering studies in the field of statistical physics had focused their efforts on developing models of neural networks that could display memory storage and retrieval. Though many associative memory models were easy to handle and still quite effective to explain the basic memory retrieval processes in the brain, they were not satisfactory under the biological point of view. It became clear to scientists that a biologically realistic neural network should have respected typical features that were observed in experiments of neurophysiology. This aspect has led to the introduction of Balanced Networks, systems where excitatory and inhibitory neurons balance their effect on each other as an emergent property of the network dynamics. One of such models is the exhibition of a mean level of neuronal activity (i.e. the average spiking rate of neurons) that is univocally defined by a linear equation in the external input. This aspect might help to reproduce what is measured in particular areas devoted to memory storage, i.e. a persistent activity during the memory retrieval performance. Even though progresses in the matter of balanced networks where achieved in the last two decades, there is still no complete theory that conciliates memory retrieval and balance in a network of neurons. The aim of this work is to develop a biologically plausible model that presents both balance and memory retrieval, building on a framework of mean field equations that can predict the theoretical behaviour of the network under the choice of a set of control parameters. We will thus measure the critical capacity of the system as a function of these parameters, comparing the theoretical results with the numerical simulations.