Almost Tight Bounds for Conflict-Free Chromatic Guarding of Orthogonal Galleries

Abstract

We address recently proposed chromatic versions of the classic Art Gallery Problem. Assume a simple polygon P is guarded by a finite set of point guards and each guard is assigned one of t colors. Such a chromatic guarding is said to be conflict-free if each point p∈ P sees at least one guard with a unique color among all guards visible from p. The goal is to establish bounds on the function cf(n) of the number of colors sufficient to guarantee the existence of a conflict-free chromatic guarding for any n-vertex polygon. B\"artschi and Suri showed cf(n)∈ O( n) (Algorithmica, 2014) for simple orthogonal polygons and the same bound applies to general simple polygons (B\"artschi et al., SoCG 2014). In this paper, we assume the r-visibility model instead of standard line visibility. Points p and q in an orthogonal polygon are r-visible to each other if the rectangle spanned by the points is contained in P. For this model we show cf(n)∈ O( n) and cf(n)∈ ( n / n). Most interestingly, we can show that the lower bound proof extends to guards with line visibility. To this end we introduce and utilize a novel discrete combinatorial structure called multicolor tableau. This is the first non-trivial lower bound for this problem setting.Furthermore, for the strong chromatic version of the problem, where all guards r-visible from a point must have distinct colors, we prove a ( n)-bound. Our results can be interpreted as coloring results for special geometric hypergraphs.