Convex geometries and directed paths on three vertices

Abstract

A convexity space is an ordered pair (V,C), where V is an arbitrary set and C is a family of subsets of V, called convex, which contains \,V\ and is closed under intersections and nested unions of its elements. For any S⊂eq V, the convex hull of S is the inclusion-wise minimum convex set C∈ C such that S⊂eq C. For a convex set C∈ C, an element p∈ C is an extreme of C if p does not belong to the convex hull of C\p\. A convexity C defined over V is a convex geometry if any convex set C∈ C is the convex hull of its extreme elements. Given an oriented graph D = (V,A), the family C of subsets of V is the P3-convexity defined over D if C is formed by all (convex) sets C⊂eq V such that no vertex v∈ V C is the central vertex of a directed path P=(u,v,w) with \u,w\ ⊂eq C, while in the P3*-convexity defined over D, we have that no vertex v∈ V C is the central vertex of a directed path P=(u,v,w) such that \u,w\ ⊂eq C and (u,w) A. In this work, we present necessary and sufficient conditions over an oriented graph D so that the P3-convexity over D is geometric, or the P3*-convexity over D is geometric. While the first case implies a polynomial-time algorithm to decide whether the P3-convexity over D is a geometric, we show that it is coNP-complete to decide whether the P3*-convexity over D is a convex geometry. We also present a family termed acyclic indifference oriented graphs and demonstrate that deciding whether the P3*-convexity in this class is geometric can be solved in polynomial-time.