Counting subgraphs in bounded-size Achlioptas processes

Abstract

Achlioptas processes such as the Bohman--Frieze process are much harder to analyse than the classical Erdos--R\'enyi process, due to the dependence between edges added at different stages. This dependence means that most analysis so far is dynamic, often based on the differential equation method. In the Erdos--R\'enyi case there is an alternative static approach, pioneered by Erdos, R\'enyi and Bollob\'as, based on evaluating the expectation (and higher moments) of various subgraph counts, and using this to study the component structure. Here we show that this latter approach can be applied (with some complications) to the Bohman--Frieze process. For example, we are able to show that the expected number μk,t,n of k-vertex tree components after tn steps satisfies (essentially) μk,t,n=ck,tn(1+O(k/n)). Our method gives a very complicated formula for ck,t, which seems to be unusable. However, since ck,t does not depend on n, we may use recent results obtained by the differential equation method and branching process analysis to find the asymptotics of ck,t as k∞. The latter results also give a formula for μk,t,n of the form ck,tn plus an error term, with a much more usable description of ck,t but a much worse error term. We combine the best of both worlds to prove a number of new results about the process near criticality. In particular, we obtain extremely sharp bounds on the size of the largest non-giant component near criticality, including the limiting distribution of its fluctuations.