On collinear sets in straight line drawings

Abstract

We consider straight line drawings of a planar graph G with possible edge crossings. The untangling problem is to eliminate all edge crossings by moving as few vertices as possible to new positions. Let fix(G) denote the maximum number of vertices that can be left fixed in the worst case. In the allocation problem, we are given a planar graph G on n vertices together with an n-point set X in the plane and have to draw G without edge crossings so that as many vertices as possible are located in X. Let fit(G) denote the maximum number of points fitting this purpose in the worst case. As fix(G) fit(G), we are interested in upper bounds for the latter and lower bounds for the former parameter. For each ε>0, we construct an infinite sequence of graphs with fit(G)=O(nσ+ε), where σ<0.99 is a known graph-theoretic constant, namely the shortness exponent for the class of cubic polyhedral graphs. To the best of our knowledge, this is the first example of graphs with fit(G)=o(n). On the other hand, we prove that fix(G)n/30 for all G with tree-width at most 2. This extends the lower bound obtained by Goaoc et al. [Discrete and Computational Geometry 42:542-569 (2009)] for outerplanar graphs. Our upper bound for fit(G) is based on the fact that the constructed graphs can have only few collinear vertices in any crossing-free drawing. To prove the lower bound for fix(G), we show that graphs of tree-width 2 admit drawings that have large sets of collinear vertices with some additional special properties.