Computational Aspects of the Colorful Carath\'eodory Theorem

Abstract

Let C1,…,Cd+1⊂ Rd be d+1 point sets, each containing the origin in its convex hull. We call these sets color classes, and we call a sequence p1, …, pd+1 with pi ∈ Ci, for i = 1, …, d+1, a colorful choice. The colorful Carath\'eodory theorem guarantees the existence of a colorful choice that also contains the origin in its convex hull. The computational complexity of finding such a colorful choice (CCP) is unknown. This is particularly interesting in the light of polynomial-time reductions from several related problems, such as computing centerpoints, to CCP. We define a novel notion of approximation that is compatible with the polynomial-time reductions to CCP: a sequence that contains at most k points from each color class is called a k-colorful choice. We present an algorithm that for any fixed > 0, outputs an ε d-colorful choice containing the origin in its convex hull in polynomial time. Furthermore, we consider a related problem of CCP: in the nearest colorful polytope problem (NCP), we are given sets C1,…,Cn⊂Rd that do not necessarily contain the origin in their convex hulls. The goal is to find a colorful choice whose convex hull minimizes the distance to the origin. We show that computing a local optimum for NCP is PLS-complete, while computing a global optimum is NP-hard.