English

Linear embeddings of graphs and graph limits

Combinatorics 2020-07-14 v3 Discrete Mathematics

Abstract

Consider a random graph process where vertices are chosen from the interval [0,1][0,1], and edges are chosen independently at random, but so that, for a given vertex xx, the probability that there is an edge to a vertex yy decreases as the distance between xx and yy increases. We call this a random graph with a linear embedding. We define a new graph parameter Γ\Gamma^*, which aims to measure the similarity of the graph to an instance of a random graph with a linear embedding. For a graph GG, Γ(G)=0\Gamma^*(G)=0 if and only if GG is a unit interval graph, and thus a deterministic example of a graph with a linear embedding. We show that the behaviour of Γ\Gamma^* is consistent with the notion of convergence as defined in the theory of dense graph limits. In this theory, graph sequences converge to a symmetric, measurable function on [0,1]2[0,1]^2. We define an operator Γ\Gamma which applies to graph limits, and which assumes the value zero precisely for graph limits that have a linear embedding. We show that, if a graph sequence {Gn}\{ G_n\} converges to a function ww, then {Γ(Gn)}\{ \Gamma^*(G_n)\} converges as well. Moreover, there exists a function ww^* arbitrarily close to ww under the box distance, so that limnΓ(Gn)\lim_{n\rightarrow \infty}\Gamma^*(G_n) is arbitrarily close to Γ(w)\Gamma (w^*).

Keywords

Cite

@article{arxiv.1210.4451,
  title  = {Linear embeddings of graphs and graph limits},
  author = {Huda Chuangpishit and Mahya Ghandehari and Matt Hurshman and Jeannette Janssen and Nauzer Kalyaniwalla},
  journal= {arXiv preprint arXiv:1210.4451},
  year   = {2020}
}

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R2 v1 2026-06-21T22:22:43.909Z