English

\v{C}ech complexes of hypercube graphs

Combinatorics 2023-11-21 v2 Algebraic Topology

Abstract

A \v{C}ech complex of a finite simple graph GG is a nerve complex of balls in the graph, with one ball centered at each vertex. More precisely, let the \v{C}ech complex N(G,r)\mathcal{N}(G,r) be the nerve of all closed balls of radius r2\frac{r}{2} centered at vertices of GG, where these balls are drawn in the geometric realization of the graph GG (equipped with the shortest path metric). The simplicial complex N(G,r)\mathcal{N}(G,r) is equal to the graph GG when r=1r=1, and homotopy equivalent to the graph GG when rr is smaller than half the length of the shortest loop in GG. For higher values of rr, the topology of N(G,r)\mathcal{N}(G,r) is not well-understood. We consider the nn-dimensional hypercube graphs In\mathbb{I}_n with 2n2^n vertices. Our main results are as follows. First, when r=2r=2, we show that the \v{C}ech complex N(In,2)\mathcal{N}(\mathbb{I}_n,2) is homotopy equivalent to a wedge of 2-spheres for all n1n\ge 1, and we count the number of 2-spheres appearing in this wedge sum. Second, when r=3r=3, we show that N(In,3)\mathcal{N}(\mathbb{I}_n,3) is homotopy equivalent to a simplicial complex of dimension at most 4, and that for n4n\ge 4 the reduced homology of N(In,3)\mathcal{N}(\mathbb{I}_n, 3) is nonzero in dimensions 3 and 4, and zero in all other dimensions. Finally, we show that for all n1n\ge 1 and r0r\ge 0, the inclusion N(In,r)N(In,r+2)\mathcal{N}(\mathbb{I}_n, r)\hookrightarrow \mathcal{N}(\mathbb{I}_n, r+2) is null-homotopic, providing a bound on the length of bars in the persistent homology of \v{C}ech complexes of hypercube graphs.

Keywords

Cite

@article{arxiv.2212.05871,
  title  = {\v{C}ech complexes of hypercube graphs},
  author = {Henry Adams and Samir Shukla and Anurag Singh},
  journal= {arXiv preprint arXiv:2212.05871},
  year   = {2023}
}

Comments

17 pages, minor changes

R2 v1 2026-06-28T07:30:54.792Z