Convex drawings of the complete graph: topology meets geometry

Abstract

In this work, we introduce and develop a theory of convex drawings of the complete graph Kn in the sphere. A drawing D of Kn is convex if, for every 3-cycle T of Kn, there is a closed disc T bounded by D[T] such that, for any two vertices u,v with D[u] and D[v] both in T, the entire edge D[uv] is also contained in T. As one application of this perspective, we consider drawings containing a non-convex K5 that has restrictions on its extensions to drawings of K7. For each such drawing, we use convexity to produce a new drawing with fewer crossings. This is the first example of local considerations providing sufficient conditions for suboptimality. In particular, we do not compare the number of crossings with the number of crossings in any known drawings. This result sheds light on Aichholzer's computer proof (personal communication) showing that, for n 12, every optimal drawing of Kn is convex. Convex drawings are characterized by excluding two of the five drawings of K5. Two refinements of convex drawings are h-convex and f-convex drawings. The latter have been shown by Aichholzer et al (Deciding monotonicity of good drawings of the complete graph, Proc.~XVI Spanish Meeting on Computational Geometry (EGC 2015), 2015) and, independently, the authors of the current article (Levi's Lemma, pseudolinear drawings of Kn, and empty triangles, J. Graph Theory DOI: 10.1002/jgt.22167), to be equivalent to pseudolinear drawings. Also, h-convex drawings are equivalent to pseudospherical drawings as demonstrated recently by Arroyo et al (Extending drawings of complete graphs into arrangements of pseudocircles, submitted).