Approximating Upper Degree-Constrained Partial Orientations

Abstract

In the Upper Degree-Constrained Partial Orientation problem we are given an undirected graph G=(V,E), together with two degree constraint functions d-,d+ : V N. The goal is to orient as many edges as possible, in such a way that for each vertex v ∈ V the number of arcs entering v is at most d-(v), whereas the number of arcs leaving v is at most d+(v). This problem was introduced by Gabow [SODA'06], who proved it to be MAXSNP-hard (and thus APX-hard). In the same paper Gabow presented an LP-based iterative rounding 4/3-approximation algorithm. Since the problem in question is a special case of the classic 3-Dimensional Matching, which in turn is a special case of the k-Set Packing problem, it is reasonable to ask whether recent improvements in approximation algorithms for the latter two problems [Cygan, FOCS'13; Sviridenko & Ward, ICALP'13] allow for an improved approximation for Upper Degree-Constrained Partial Orientation. We follow this line of reasoning and present a polynomial-time local search algorithm with approximation ratio 5/4+. Our algorithm uses a combination of two types of rules: improving sets of bounded pathwidth from the recent 4/3+-approximation algorithm for 3-Set Packing [Cygan, FOCS'13], and a simple rule tailor-made for the setting of partial orientations. In particular, we exploit the fact that one can check in polynomial time whether it is possible to orient all the edges of a given graph [Gy\'arf\'as & Frank, Combinatorics'76].