Purely Combinatorial Algorithms for Approximate Directed Minimum Degree Spanning Trees

Abstract

Given a directed graph G on n vertices with a special vertex s, the directed minimum degree spanning tree problem requires computing a incoming spanning tree rooted at s whose maximum tree in-degree is the smallest among all such trees. The problem is known to be NP-hard, since it generalizes the Hamiltonian path problem. The best LP-based polynomial time algorithm can achieve an approximation of *+2 [Bansal et al, 2009], where * denotes the optimal maximum tree in-degree. As for purely combinatorial algorithms (algorithms that do not use LP), the best approximation is O(*+ n) [Krishnan and Raghavachari, 2001] but the running time is quasi-polynomial. In this paper, we focus on purely combinatorial algorithms and try to bridge the gap between LP-based approaches and purely combinatorial approaches. As a result, we propose a purely combinatorial polynomial time algorithm that also achieves an O(* + n) approximation. Then we improve this algorithm to obtain a (1+ε)* + O( n n) for any constant 0<ε<1 approximation in polynomial time.