Neural ring homomorphisms and maps between neural codes
Abstract
Neural codes are binary codes that are used for information processing and representation in the brain. In previous work, we have shown how an algebraic structure, called the {\it neural ring}, can be used to efficiently encode geometric and combinatorial properties of a neural code [1]. In this work, we consider maps between neural codes and the associated homomorphisms of their neural rings. In order to ensure that these maps are meaningful and preserve relevant structure, we find that we need additional constraints on the ring homomorphisms. This motivates us to define {\it neural ring homomorphisms}. Our main results characterize all code maps corresponding to neural ring homomorphisms as compositions of 5 elementary code maps. As an application, we find that neural ring homomorphisms behave nicely with respect to convexity. In particular, if and are convex codes, the existence of a surjective code map with a corresponding neural ring homomorphism implies that the minimal embedding dimensions satisfy .
Cite
@article{arxiv.1511.00255,
title = {Neural ring homomorphisms and maps between neural codes},
author = {Carina Curto and Nora Youngs},
journal= {arXiv preprint arXiv:1511.00255},
year = {2019}
}
Comments
15 pages, 2 figures