Coloring Hypergraphs Induced by Dynamic Point Sets and Bottomless Rectangles

Asinowski, Andrei; Cardinal, Jean; Cohen, Nathann; Collette, Sébastien; Hackl, Thomas; Hoffmann, Michael M.; Knauer, Kolja; Langerman, Stefan; Lasoń, Michał; Micek, Piotr; Rote, Günter; Ueckerdt, Torsten

doi:10.1007/978-3-642-40104-6_7

Cited by 20 publications

(34 citation statements)

References 21 publications

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“…Motivated by these, bottomless rectangles are regarded for small values in [11,12] and polychromatic k-colorings in [1]. In this paper we place bottomless rectangles in our abstract context and pose some further problems about them.…”

Section: Introductionmentioning

confidence: 99%

An Abstract Approach to Polychromatic Coloring: Shallow Hitting Sets in ABA-free Hypergraphs and Pseudohalfplanes

Keszegh

Pálvölgyi

2016

Lecture Notes in Computer Science

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The goal of this paper is to give a new, abstract approach to cover-decomposition and polychromatic colorings using hypergraphs on ordered vertex sets. We introduce an abstract version of a framework by Smorodinsky and Yuditsky, used for polychromatic coloring halfplanes, and apply it to so-called ABA-free hypergraphs, which are a generalization of interval graphs. Using our methods, we prove that (2k − 1)-uniform ABA-free hypergraphs have a polychromatic k-coloring, a problem posed by the second author. We also prove the same for hypergraphs defined on a point set by pseudohalfplanes. These results are best possible. We could only prove slightly weaker results for dual hypergraphs defined by pseudohalfplanes, and for hypergraphs defined by pseudohalfspheres. We also introduce another new notion that seems to be important for investigating polychromatic colorings and ǫ-nets, shallow hitting sets. We show that all the above hypergraphs have shallow hitting sets, if their hyperedges are containment-free.

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Section: Introductionmentioning

confidence: 99%

An Abstract Approach to Polychromatic Coloring: Shallow Hitting Sets in ABA-free Hypergraphs and Pseudohalfplanes

Keszegh

Pálvölgyi

2016

Lecture Notes in Computer Science

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“…It can be expressed as coloring points appearing on a line in such a way that at all times any interval containing p(k) points contains one point of each color, or equivalently, coloring point sets in the plane such that every bottomless rectangle containing p(k) points contains a point of each color. In [5] it is shown that in this case a linear upper bound on p(k) can be achieved with a semi-online coloring algorithm or equivalently a sweeping line algorithm. 4…”

Section: 2mentioning

confidence: 99%

“…This setting can be thought of as points appearing on a line, and we want to color the points with k colors such that at any time, any set of p(k) consecutive points contains at least one of each color. This problem has been studied by a number of authors, whose results were compiled in a joint paper [5]. In particular, they showed that under this restriction, we have 1.6k p(k) 3k−2.…”

Section: Theorem 3 ([19]mentioning

confidence: 99%

Making Octants Colorful and Related Covering Decomposition Problems

Cardinal¹,

Knauer²,

Micek³

et al. 2014

SIAM J. Discrete Math.

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We give new positive results on the long-standing open problem of geometric covering decomposition for homothetic polygons. In particular, we prove that for any positive integer k, every finite set of points in R 3 can be colored with k colors so that every translate of the negative octant containing at least k 6 points contains at least one of each color. The best previously known bound was doubly exponential in k. This yields, among other corollaries, the first polynomial bound for the decomposability of multiple coverings by homothetic triangles. We also investigate related decomposition problems involving intervals appearing on a line. We prove that no algorithm can dynamically maintain a decomposition of a multiple covering by intervals under insertion of new intervals, even in a semi-online model, in which some coloring decisions can be delayed. This implies that a wide range of sweeping plane algorithms cannot guarantee any bound even for special cases of the octant problem.A preliminary version of this paper was presented at the 2014 ACM-SIAM Symposium on Discrete Algorithms (SODA'14).Journal version of this paper is submitted to SIAM J. Discrete Math.

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Section: Corollarymentioning

confidence: 99%

Making Octants Colorful and Related Covering Decomposition Problems

Cardinal¹,

Knauer²,

Micek³

et al. 2013

Proceedings of the Twenty-Fifth Annual ACM-SIAM Symposium on Discrete Algorithms

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Abstract. We give new positive results on the long-standing open problem of geometric covering decomposition for homothetic polygons. In particular, we prove that for any positive integer k, every finite set of points in R 3 can be colored with k colors so that every translate of the negative octant containing at least k 6 points contains at least one of each color. The best previously known bound was doubly exponential in k. This yields, among other corollaries, the first polynomial bound for the decomposability of multiple coverings by homothetic triangles. We also investigate related decomposition problems involving intervals appearing on a line. We prove that no algorithm can dynamically maintain a decomposition of a multiple covering by intervals under insertion of new intervals, even in a semi-online model, in which some coloring decisions can be delayed. This implies that a wide range of sweeping plane algorithms cannot guarantee any bound even for special cases of the octant problem.

show abstract

Coloring Hypergraphs Induced by Dynamic Point Sets and Bottomless Rectangles

Cited by 20 publications

References 21 publications

An Abstract Approach to Polychromatic Coloring: Shallow Hitting Sets in ABA-free Hypergraphs and Pseudohalfplanes

An Abstract Approach to Polychromatic Coloring: Shallow Hitting Sets in ABA-free Hypergraphs and Pseudohalfplanes

Making Octants Colorful and Related Covering Decomposition Problems

Making Octants Colorful and Related Covering Decomposition Problems

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