Cech complexes of hypercube graphs

Abstract

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

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