Flexible Memory Networks
Abstract
Networks of neurons in some brain areas are flexible enough to encode new memories quickly. Using a standard firing rate model of recurrent networks, we develop a theory of flexible memory networks. Our main results characterize networks having the maximal number of flexible memory patterns, given a constraint graph on the network's connectivity matrix. Modulo a mild topological condition, we find a close connection between maximally flexible networks and rank 1 matrices. The topological condition is H_1(X;Z)=0, where X is the clique complex associated to the network's constraint graph; this condition is generically satisfied for large random networks that are not overly sparse. In order to prove our main results, we develop some matrix-theoretic tools and present them in a self-contained section independent of the neuroscience context.
Cite
@article{arxiv.1009.4958,
title = {Flexible Memory Networks},
author = {Carina Curto and Anda Degeratu and Vladimir Itskov},
journal= {arXiv preprint arXiv:1009.4958},
year = {2015}
}
Comments
Accepted to Bulletin of Mathematical Biology, 11 July 2011