Normal to Poisson phase transition for subgraph counting in the random-connection model (2409.16222v1)

Abstract: This paper studies the limiting behavior of the count of subgraphs isomorphic to a graph $G$ with $m\geq 0$ fixed endpoints in the random-connection model, as the intensity $\lambda$ of the underlying Poisson point process tends to infinity. When connection probabilities are of order $\lambda^{-\alpha}$ we identify a phase transition phenomenon via a critical decay rate $\alpha^\ast_m (G)>0$ such that normal approximation for subgraph counts holds when $\alpha \in (0,\alpha^\ast_m (G) )$, and a Poisson limit result holds if $\alpha = \alpha^\ast_m (G)$. Our method relies on cumulant growth rates derived by the convex analysis of planar diagrams that list the partitions involved in cumulant identities. As a result, by the cumulant method we obtain normal approximation results with convergence rates in the Kolmogorov distance, and a Poisson limit theorem, for subgraph counts.