A binary Hopfield network with 1/(n) information rate and applications to grid cell decoding

Abstract

A Hopfield network is an auto-associative, distributive model of neural memory storage and retrieval. A form of error-correcting code, the Hopfield network can learn a set of patterns as stable points of the network dynamic, and retrieve them from noisy inputs -- thus Hopfield networks are their own decoders. Unlike in coding theory, where the information rate of a good code (in the Shannon sense) is finite but the cost of decoding does not play a role in the rate, the information rate of Hopfield networks trained with state-of-the-art learning algorithms is of the order (n)/n, a quantity that tends to zero asymptotically with n, the number of neurons in the network. For specially constructed networks, the best information rate currently achieved is of order 1/n. In this work, we design simple binary Hopfield networks that have asymptotically vanishing error rates at an information rate of 1/(n). These networks can be added as the decoders of any neural code with noisy neurons. As an example, we apply our network to a binary neural decoder of the grid cell code to attain information rate 1/(n).