English

Random tree-weighted graphs

Probability 2021-01-25 v2 Combinatorics

Abstract

For each n1n \ge 1, let dn=(dn(i),1in)\mathrm{d}^n=(d^{n}(i),1 \le i \le n) be a sequence of positive integers with even sum i=1ndn(i)2n\sum_{i=1}^n d^n(i) \ge 2n. Let (Gn,Tn,Γn)(G_n,T_n,\Gamma_n) be uniformly distributed over the set of simple graphs GnG_n with degree sequence dn\mathrm{d}^n, endowed with a spanning tree TnT_n and rooted along an oriented edge Γn\Gamma_n of GnG_n which is not an edge of TnT_n. Under a finite variance assumption on degrees in GnG_n, we show that, after rescaling, TnT_n converges in distribution to the Brownian continuum random tree as nn \to \infty. Our main tool is a new version of Pitman's additive coalescent (https://doi.org/10.1006/jcta.1998.2919), which can be used to build both random trees with a fixed degree sequence, and random tree-weighted graphs with a fixed degree sequence. As an input to the proof, we also derive a Poisson approximation theorem for the number of loops and multiple edges in the superposition of a fixed graph and a random graph with a given degree sequence sampled according to the configuration model; we find this to be of independent interest.

Keywords

Cite

@article{arxiv.2008.12167,
  title  = {Random tree-weighted graphs},
  author = {Louigi Addario-Berry and Jordan Barrett},
  journal= {arXiv preprint arXiv:2008.12167},
  year   = {2021}
}

Comments

38 pages; version 2 has several minor corrections pointed out by a referee, and also corrects the proof of Corollary 4.2, which previously failed to address the case that $G_n$ has $(1+o(1))n$ edges

R2 v1 2026-06-23T18:08:38.918Z