Neural ideals and stimulus space visualization
Abstract
A neural code is a collection of binary vectors of a given length n that record the co-firing patterns of a set of neurons. Our focus is on neural codes arising from place cells, neurons that respond to geographic stimulus. In this setting, the stimulus space can be visualized as subset of covered by a collection of convex sets such that the arrangement forms an Euler diagram for . There are some methods to determine whether such a convex realization exists; however, these methods do not describe how to draw a realization. In this work, we look at the problem of algorithmically drawing Euler diagrams for neural codes using two polynomial ideals: the neural ideal, a pseudo-monomial ideal; and the neural toric ideal, a binomial ideal. In particular, we study how these objects are related to the theory of piercings in information visualization, and we show how minimal generating sets of the ideals reveal whether or not a code is , , or -inductively pierced.
Cite
@article{arxiv.1607.00697,
title = {Neural ideals and stimulus space visualization},
author = {Elizabeth Gross and Nida Kazi Obatake and Nora Youngs},
journal= {arXiv preprint arXiv:1607.00697},
year = {2016}
}