English

String graphs are quasi-isometric to planar graphs

Combinatorics 2026-04-03 v2 Discrete Mathematics Group Theory Geometric Topology Metric Geometry

Abstract

We prove that for every countable string graph SS, there is a planar graph GG with V(G)=V(S)V(G)=V(S) such that 123660800dS(u,v)dG(u,v)162dS(u,v) \frac{1}{23660800}d_S(u,v) \le d_G(u,v) \le 162 d_S(u,v) for all u,vV(S)u,v\in V(S), where dS(u,v)d_S(u,v), dG(u,v)d_G(u,v) denotes the distance between uu and vv in SS and GG respectively. In other words, string graphs are quasi-isometric to planar graphs. This theorem lifts a number of theorems from planar graphs to string graphs, we give some examples. String graphs have Assouad-Nagata (and asymptotic dimension) at most 2. Connected, locally finite, quasi-transitive string graphs are accessible. A finitely generated group Γ\Gamma is virtually a free product of free and surface groups if and only if Γ\Gamma is quasi-isometric to a string graph. Two further corollaries are that countable planar metric graphs and complete Riemannian planes are also quasi-isometric to planar graphs, which answers a question of Georgakopoulos and Papasoglu. For finite string graphs and planar metric graphs, our proofs yield polynomial time (for string graphs, this is in terms of the size of a representation given in the input) algorithms for generating such quasi-isometric planar graphs. We further extend our techniques to show that every complete Riemannian surfaces Σ\Sigma of bounded Euler genus has a triangulation GΣG\subset \Sigma such that G(1)ΣG^{(1)} \hookrightarrow \Sigma is a quasi-isometry, where G(1)G^{(1)} is the simplicial 1-skeleton of GG.

Keywords

Cite

@article{arxiv.2510.19602,
  title  = {String graphs are quasi-isometric to planar graphs},
  author = {James Davies},
  journal= {arXiv preprint arXiv:2510.19602},
  year   = {2026}
}

Comments

35 pages, 9 figures, v2: Adds an additional result on Riemannian surfaces

R2 v1 2026-07-01T06:59:49.363Z