English

Sparse graphs: metrics and random models

Probability 2010-02-10 v3 Combinatorics

Abstract

Recently, Bollob\'as, Janson and Riordan introduced a family of random graph models producing inhomogeneous graphs with nn vertices and Θ(n)\Theta(n) edges whose distribution is characterized by a kernel, i.e., a symmetric measurable function \ka:[0,1]2[0,)\ka:[0,1]^2 \to [0,\infty). To understand these models, we should like to know when different kernels \ka\ka give rise to `similar' graphs, and, given a real-world network, how `similar' is it to a typical graph G(n,\ka)G(n,\ka) derived from a given kernel \ka\ka. The analogous questions for dense graphs, with Θ(n2)\Theta(n^2) edges, are answered by recent results of Borgs, Chayes, Lov\'asz, S\'os, Szegedy and Vesztergombi, who showed that several natural metrics on graphs are equivalent, and moreover that any sequence of graphs converges in each metric to a graphon, i.e., a kernel taking values in [0,1][0,1]. Possible generalizations of these results to graphs with o(n2)o(n^2) but ω(n)\omega(n) edges are discussed in a companion paper [arXiv:0708.1919]; here we focus only on graphs with Θ(n)\Theta(n) edges, which turn out to be much harder to handle. Many new phenomena occur, and there are a host of plausible metrics to consider; many of these metrics suggest new random graph models, and vice versa.

Keywords

Cite

@article{arxiv.0812.2656,
  title  = {Sparse graphs: metrics and random models},
  author = {Bela Bollobas and Oliver Riordan},
  journal= {arXiv preprint arXiv:0812.2656},
  year   = {2010}
}

Comments

44 pages, 1 figure. This is a companion paper to arXiv:0708.1919, consisting of an updated version of part of the original version (arXiv:0708.1919v1), which has been split into two papers. Since v1, references updated and other very minor changes. To appear in Random Structures and Algorithms

R2 v1 2026-06-21T11:51:53.518Z