Tight bounds for intersection-reverse sequences, edge-ordered graphs and applications
Abstract
In 2006, Marcus and Tardos proved that if are cyclic orders on some subsets of a set of symbols such that the common elements of any two distinct orders and appear in reversed cyclic order in and , then . This result is tight up to the logarithmic factor and has since become an important tool in Discrete Geometry. We improve this to the optimal bound . In fact, we show that if are linear orders on some subsets of a set of symbols such that no three symbols appear in the same order in any two distinct linear orders, then . Using this result, we resolve several open problems in Discrete Geometry and Extremal Graph Theory as follows. We prove that every -vertex topological graph that does not contain a self-crossing four-cycle has edges. This resolves a problem of Marcus and Tardos from 2006. We also show that pseudo-circles in the plane can be cut into pseudo-segments, which, in turn, implies new bounds on point-circle incidences and on other geometric problems. Moreover, we prove that the edge-ordered Tur\'an number of the four-cycle is . This answers a question of Gerbner, Methuku, Nagy, P\'alv\"olgyi, Tardos and Vizer. Using different methods, we determine the largest possible extremal number that an edge-ordered forest of order chromatic number two can have. Kucheriya and Tardos showed that every such graph has extremal number at most , and conjectured that this can be improved to . We disprove their conjecture by showing that for every , there exists an edge-ordered tree of order chromatic number two whose extremal number is .
Keywords
Cite
@article{arxiv.2411.07188,
title = {Tight bounds for intersection-reverse sequences, edge-ordered graphs and applications},
author = {Barnabás Janzer and Oliver Janzer and Abhishek Methuku and Gábor Tardos},
journal= {arXiv preprint arXiv:2411.07188},
year = {2024}
}
Comments
16 pages