Abstract
Several classical constructions illustrate the fact that the chromatic number of a graph can be arbitrarily large compared to its clique number. However, until very recently, no such construction was known for intersection graphs of geometric objects in the plane. We provide a general construction that for any arc-connected compact set $X$ in $\mathbb{R}^2$ that is not an axis-aligned rectangle and for any positive integer $k$ produces a family $\mathcal{F}$ of sets, each obtained by an independent horizontal and vertical scaling and translation of $X$, such that no three sets in $\mathcal{F}$ pairwise intersect and $\chi(\mathcal{F})>k$. This provides a negative answer to a question of Gyarfas and Lehel for L-shapes. With extra conditions, we also show how to construct a triangle-free family of homothetic (uniformly scaled) copies of a set with arbitrarily large chromatic number. This applies to many common shapes, like circles, square boundaries, and equilateral L-shapes. Additionally, we reveal a surprising connection between coloring geometric objects in the plane and on-line coloring of intervals on the line.
Highlights
A proper coloring of a graph is an assignment of colors to the vertices of the graph such that no two adjacent ones are assigned the same color
With extra conditions we show how to construct a triangle-free family of homothetic copies of a set with arbitrarily large chromatic number
We focus on the relation between the chromatic number and the clique number for classes of graphs arising from geometry
Summary
A proper coloring of a graph is an assignment of colors to the vertices of the graph such that no two adjacent ones are assigned the same color. The study of the chromatic number of intersection graphs of geometric objects in R2 was initiated in the seminal paper of Asplund and Grünbaum [1], where they proved that the families of axis-aligned rectangles are χ -bounded. On the other hand, Burling [3] showed that triangle-free intersection graphs of axis-aligned boxes in R3 can have arbitrarily large chromatic number. For every positive integer k we present a triangle-free family F of sets, each obtained by translation and independent horizontal and vertical scaling of X , such that χ (F) > k This applies to a wide range of geometric shapes like axis-aligned ellipses, rhombuses, rectangular frames, cross-shapes, L-shapes, etc. We give an alternative presentation of the construction of triangle-free families of rectangular frames (that is, boundaries of axis-aligned rectangles) with arbitrarily large chromatic number
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