Excluding an induced star in dense random graphs

Abstract

For fixed k≥3, we study the asymptotic number and typical structure of dense graphs with no induced copy of the star K1,k. We solve the associated graphon variational problems both at fixed constant edge density γ and for the conditioned Erdős--Rényi random graph G(n,p) for constant p. As consequences, we obtain explicit formulas for the entropy density of induced-K1,k-free graphs with Θ(n2) edges and for the large deviation rate function for the event that G(n,p) is induced-K1,k-free. The entropy density exhibits a second-order phase transition at an explicit critical density γk, while the rate function exhibits a first-order phase transition at a critical parameter pk. We completely characterize the optimizers of both variational problems. Both models have parameter values for which there are infinitely many optimal graphons, but there is always a unique graphon that represents the typical structure in cut metric. We refine the graphon-level results by giving a detailed structural description of both models. For supercritical parameters, each random graph model is the complement of a (k-1)-partite graph with high probability. In the subcritical regime of the fixed-density model, the typical structure is the disjoint union of the complement of a (k-1)-partite graph, and a sparse remainder. In the subcritical regime of the conditioned Erdős--Rényi random graph, a typical sample has o(n2) edges.