Your search keyword '"Damásdi, Gábor"' showing total 4 results

1. Orientation of good covers

Author

Ágoston, Péter, Damásdi, Gábor, Keszegh, Balázs, and Pálvölgyi, Dömötör

Subjects

FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 52C99

Abstract

We study systems of orientations on triples that satisfy the following so-called interiority condition: $\circlearrowleft(ABD)=~\circlearrowleft(BCD)=~\circlearrowleft(CAD)=1$ implies $\circlearrowleft(ABC)=1$ for any $A,B,C,D$. We call such an orientation a P3O (partial 3-order), a natural generalization of a poset, that has several interesting special cases. For example, the order type of a planar point set (that can have collinear triples) is a P3O; we denote a P3O realizable by points as p-P3O. If we do not allow $\circlearrowleft(ABC)=0$, we obtain a T3O (total 3-order). Contrary to linear orders, a T3O can have a rich structure. A T3O realizable by points, a p-T3O, is the order type of a point set in general position. In our paper "Orientation of convex sets" we defined a 3-order on pairwise intersecting convex sets; such a P3O is called a C-P3O. In this paper we extend this 3-order to pairwise intersecting good covers; such a P3O is called a GC-P3O. If we do not allow $\circlearrowleft(ABC)=0$, we obtain a C-T3O and a GC-T3O, respectively. The main result of this paper is that there is a p-T3O that is not a GC-T3O, implying also that it is not a C-T3O -- this latter problem was left open in our earlier paper. Our proof involves several combinatorial and geometric observations that can be of independent interest. Along the way, we define several further special families of GC-T3O's.

Published

2022

2. Three-Chromatic Geometric Hypergraphs

Author

Damásdi, Gábor and Pálvölgyi, Dömötör

Subjects

Discrete geometry, Geometric hypergraph coloring, Mathematics - Combinatorics, Decomposition of multiple coverings, Mathematics of computing → Hypergraphs, Computer Science - Discrete Mathematics

Abstract

We prove that for any planar convex body C there is a positive integer m with the property that any finite point set P in the plane can be three-colored such that there is no translate of C containing at least m points of P, all of the same color. As a part of the proof, we show a strengthening of the Erdős-Sands-Sauer-Woodrow conjecture. Surprisingly, the proof also relies on the two dimensional case of the Illumination conjecture., LIPIcs, Vol. 224, 38th International Symposium on Computational Geometry (SoCG 2022), pages 32:1-32:13

Published

2022

3. Orientation of convex sets

Author

Ágoston, Péter, Damásdi, Gábor, Keszegh, Balázs, and Pálvölgyi, Dömötör

Subjects

FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 52C99

Abstract

We introduce a novel definition of orientation on the triples of a family of pairwise intersecting planar convex sets and study its properties. In particular, we compare it to other systems of orientations on triples that satisfy a so-called interiority condition: $\circlearrowleft(ABD)=~\circlearrowleft(BCD)=~\circlearrowleft(CAD)=1$ imply $\circlearrowleft(ABC)=1$ for any $A,B,C,D$. We call such an orientation a P3O (partial 3-order), a natural generalization of a poset, that has several interesting special cases. For example, the order type of a planar point set (that can have collinear triples) is a P3O; we denote a P3O realizable by points as p-P3O. If we do not allow $\circlearrowleft(ABC)=0$, we obtain a T3O (total 3-order). Contrary to linear orders, a T3O can have a rich structure. A T3O realizable by points, a p-T3O, is the order type of a point set in general position. Despite these similarities to order types, P3O and p-T3O that can arise from the orientation of pairwise intersecting convex sets, denoted by C-P3O and C-T3O, turn out to be quite different from order types: there is no containment relation among the family of all C-P3O's and the family of all p-P3O's, or among the families of C-T3O's and p-T3O's. Finally, we study properties of these orientations if we also require that the family of underlying convex sets satisfies the (4,3) property.

Published

2022

4. The Zarankiewicz problem, cages and geometries

Author

Damásdi, Gábor, Héger, Tamás, and Szőnyi, Tamás

Published

2013