Graph invariants from the topology of rigid isotopy classes

Abstract

We define a new family of graph invariants, studying the topology of the moduli space of their geometric realizations in Euclidean spaces, using a limiting procedure reminiscent of Floer homology. Given a labeled graph G on n vertices and d ≥ 1, WG, d ⊂eq Rd × n denotes the space of nondegenerate realizations of G in Rd.The set WG, d might not be connected, even when it is nonempty, and we refer to its connected components as rigid isotopy classes of G in Rd. We study the topology of these rigid isotopy classes. First, regarding the connectivity of WG, d, we generalize a result of Maehara that WG, d is nonempty for d ≥ n to show that WG, d is k-connected for d ≥ n + k + 1, and so WG, ∞ is always contractible. While πk(WG, d) = 0 for G, k fixed and d large enough, we also prove that, in spite of this, when d ∞ the structure of the nonvanishing homology of WG, d exhibits a stabilization phenomenon: it consists of (n-1) equally spaced clusters whose shape does not depend on d, for d large enough. This leads to the definition of a family of graph invariants, capturing this structure. For instance, the sum of the Betti numbers of WG,d does not depend on d, for d large enough; we call this number the Floer number of the graph G. Finally, we give asymptotic estimates on the number of rigid isotopy classes of Rd--geometric graphs on n vertices for d fixed and n tending to infinity. When d=1 we show that asymptotically as n ∞ each isomorphism class corresponds to a constant number of rigid isotopy classes, on average. For d>1 we prove a similar statement at the logarithmic scale.