English

A polynomial bound for untangling geometric planar graphs

Computational Geometry 2010-05-31 v2 Discrete Mathematics Combinatorics

Abstract

To untangle a geometric graph means to move some of the vertices so that the resulting geometric graph has no crossings. Pach and Tardos [Discrete Comput. Geom., 2002] asked if every n-vertex geometric planar graph can be untangled while keeping at least n^\epsilon vertices fixed. We answer this question in the affirmative with \epsilon=1/4. The previous best known bound was \Omega((\log n / \log\log n)^{1/2}). We also consider untangling geometric trees. It is known that every n-vertex geometric tree can be untangled while keeping at least (n/3)^{1/2} vertices fixed, while the best upper bound was O(n\log n)^{2/3}. We answer a question of Spillner and Wolff [arXiv:0709.0170 2007] by closing this gap for untangling trees. In particular, we show that for infinitely many values of n, there is an n-vertex geometric tree that cannot be untangled while keeping more than 3(n^{1/2}-1) vertices fixed. Moreover, we improve the lower bound to (n/2)^{1/2}.

Keywords

Cite

@article{arxiv.0710.1641,
  title  = {A polynomial bound for untangling geometric planar graphs},
  author = {Prosenjit Bose and Vida Dujmovic and Ferran Hurtado and Stefan Langerman and Pat Morin and David R. Wood},
  journal= {arXiv preprint arXiv:0710.1641},
  year   = {2010}
}

Comments

14 pages, 7 figures

R2 v1 2026-06-21T09:28:38.450Z