Counting connected hypergraphs via the probabilistic method

Abstract

In 1990 Bender, Canfield and McKay gave an asymptotic formula for the number of connected graphs on [n] with m edges, whenever n and the nullity m-n+1 tend to infinity. Asymptotic formulae for the number of connected r-uniform hypergraphs on [n] with m edges and so nullity t=(r-1)m-n+1 were proved by Karo\'nski and uczak for the case t=o( n/ n), and Behrisch, Coja-Oghlan and Kang for t=(n). Here we prove such a formula for any r 3 fixed, and any t=t(n) satisfying t=o(n) and t∞ as n∞. This leaves open only the (much simpler) case t/n∞, which we will consider in future work. ( arXiv:1511.04739 ) Our approach is probabilistic. Let Hrn,p denote the random r-uniform hypergraph on [n] in which each edge is present independently with probability p. Let L1 and M1 be the numbers of vertices and edges in the largest component of Hrn,p. We prove a local limit theorem giving an asymptotic formula for the probability that L1 and M1 take any given pair of values within the `typical' range, for any p=p(n) in the supercritical regime, i.e., when p=p(n)=(1+ε(n))(r-2)!n-r+1 where ε3n∞ and ε 0; our enumerative result then follows easily. Taking as a starting point the recent joint central limit theorem for L1 and M1, we use smoothing techniques to show that `nearby' pairs of values arise with about the same probability, leading to the local limit theorem. Behrisch et al used similar ideas in a very different way, that does not seem to work in our setting. Independently, Sato and Wormald have recently proved the special case r=3, with an additional restriction on t. They use complementary, more enumerative methods, which seem to have a more limited scope, but to give additional information when they do work.