Spectrum and local weak convergence of sparse random uniform hypergraphs

Abstract

The notion of local weak convergence, or Benjamini--Schramm convergence, was introduced by Benjamini and Schramm. The local weak limit of sparse Erd os--R\'enyi graphs is the Galton--Watson measure with Poisson offspring almost surely. Recently, Adhikari, Kumar, and Saha showed that the line graph of sparse Linial--Meshulam complexes converges to the d-block Galton--Watson measure. We study a unified model: weighted line graphs of sparse k-uniform random hypergraphs on n vertices. Let H(n,k,p) be the k-uniform random hypergraph where each k-subset of [n] is included as a hyperedge independently with probability p. For a k-uniform hypergraph H=(V,E) and 1 r k-1, define the r-set weighted line graph Gr(H)=( Vr, Er,wH) by Vr=[nr], Er=\\τ1,τ2\:τ1,τ2∈ Vr,\ ∃ e∈ E s.t. τ1,τ2⊂ e\, with weight wH(\τ1,τ2\)=|\e∈ E:τ1,τ2⊂ e\|. In particular, G1(Hn) generalizes Erd os--R\'enyi graphs and Gk-1(Hn) is the line graph of the Linial--Meshulam complex. We show that if n-rk-r λ as n∞, then Gr(Hn) converges locally to the (kr-1)-block Galton--Watson measure with Poisson(λ) offspring almost surely. As a consequence, we obtain the limiting spectral distribution of the adjacency matrices of Gr(Hn).