Coloring Geometric Hypergraphs: A Survey
Abstract
The chromatic number of a hypergraph is the smallest number of colors needed to color the vertices such that no edge of at least two vertices is monochromatic. Given a family of geometric objects F that covers a subset S of the Euclidean space, we can associate it with a hypergraph whose vertex set is F and whose edges are those subsets F'⊂ F for which there exists a point p∈ S such that F' consists of precisely those elements of F that contain p. The question whether F can be split into 2 coverings is equivalent to asking whether the chromatic number of the hypergraph is equal to 2. There are a number of competing notions of the chromatic number that lead to deep combinatorial questions already for abstract hypergraphs. In this paper, we concentrate on geometrically defined (in short, geometric) hypergraphs, and survey many recent coloring results related to them. In particular, we study and survey the following problem, dual to the above covering question. Given a set of points S in the Euclidean space and a family F of geometric objects of a fixed type, define a hypergraph Hm on the point set S, whose edges are the subsets of S that can be obtained as the intersection of S with a member of F and have at least m elements. Is it true that if m is large enough, then the chromatic number of Hm is equal to 2?
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