The Leray Dimension of a Convex Code

Abstract

Convex codes were recently introduced as models for neural codes in the brain. Any convex code has an associated minimal embedding dimension d(), which is the minimal Euclidean space dimension such that the code can be realized by a collection of convex open sets. In this work we import tools from combinatorial commutative algebra in order to obtain better bounds on d() from an associated simplicial complex (). In particular, we make a connection to minimal free resolutions of Stanley-Reisner ideals, and observe that they contain topological information that provides stronger bounds on d(). This motivates us to define the Leray dimension dL(), and show that it can be obtained from the Betti numbers of such a minimal free resolution. We compare dL() to two previously studied dimension bounds, obtained from Helly's theorem and the simplicial homology of (). Finally, we show explicitly how dL() can be computed algebraically, and illustrate this with examples.