Coloring Hypergraphs Induced by Dynamic Point Sets and Bottomless Rectangles

We consider a coloring problem on dynamic, one-dimensional point sets: points appearing and disappearing on a line at given times. We wish to color them with k colors so that at any time, any sequence of p(k) consecutive points, for some function p, contains at least one point of each color. We prove that no such function p(k) exists in general. However, in the restricted case in which points appear gradually, but never disappear, we give a coloring algorithm guaranteeing the property at any time with p(k)=3k−2. This can be interpreted as coloring point sets in ℝ2 with k colors such that any bottomless rectangle containing at least 3k−2 points contains at least one point of each color. Here a bottomless rectangle is an axis-aligned rectangle whose bottom edge is below the lowest point of the set. For this problem, we also prove a lower bound p(k)>ck, where c>1.67. Hence, for every k there exists a point set, every k-coloring of which is such that there exists a bottomless rectangle containing ck points and missing at least one of the k colors. Chen et al. (2009) proved that no such function p(k) exists in the case of general axis-aligned rectangles. Our result also complements recent results from Keszegh and Palvolgyi on cover-decomposability of octants (2011, 2012).

[1]  Jean Cardinal,et al.  Coloring Geometric Range Spaces , 2009, Discret. Comput. Geom..

[2]  János Pach,et al.  Tight lower bounds for the size of epsilon-nets , 2010, SoCG '11.

[3]  János Pach,et al.  Delaunay graphs of point sets in the plane with respect to axis‐parallel rectangles , 2008, SODA '08.

[4]  Jean Cardinal,et al.  Decomposition of Multiple Coverings into More Parts , 2008, SODA.

[5]  Shakhar Smorodinsky,et al.  Polychromatic coloring for half-planes , 2012, J. Comb. Theory, Ser. A.

[6]  János Pach,et al.  Coloring Axis-Parallel Rectangles , 2007, KyotoCGGT.

[7]  János Pach,et al.  Decomposition of multiple coverings into many parts , 2007, SCG '07.

[8]  Balázs Keszegh,et al.  Weak Conflict-Free Colorings of Point Sets and Simple Regions , 2007, CCCG.

[9]  János Pach,et al.  Coloring axis-parallel rectangles , 2010, J. Comb. Theory, Ser. A.

[10]  Balázs Keszegh,et al.  Octants Are Cover-Decomposable , 2012, Discret. Comput. Geom..

[11]  János Pach,et al.  Research problems in discrete geometry , 2005 .

[12]  Balázs Keszegh,et al.  Octants are cover-decomposable into many coverings , 2014, Comput. Geom..

[13]  Dömötör Pálvölgyi,et al.  Indecomposable Coverings with Concave Polygons , 2010, Discret. Comput. Geom..

[14]  Ellen Gethner,et al.  Bar k-Visibility Graphs , 2007, J. Graph Algorithms Appl..

[15]  Jean Cardinal,et al.  Colorful Strips , 2011, Graphs Comb..

[16]  Kasturi R. Varadarajan Weighted geometric set cover via quasi-uniform sampling , 2010, STOC '10.

[17]  János Pach,et al.  Covering the plane with convex polygons , 1986, Discret. Comput. Geom..

[18]  János Pach,et al.  Indecomposable Coverings , 2005, Canadian Mathematical Bulletin.

[19]  Matt Gibson,et al.  Optimally Decomposing Coverings with Translates of a Convex Polygon , 2011, Discret. Comput. Geom..

[20]  Géza Tóth,et al.  Convex Polygons are Cover-Decomposable , 2010, Discret. Comput. Geom..