Internally-disjoint Pendant Steiner Trees in Digraphs

Abstract

For a digraph D=(V(D),A(D)) and a set S⊂eq V(D) with |S|≥ 2 and r∈ S, a directed pendant (S,r)-Steiner tree (or, simply, a pendant (S,r)-tree) is an out-tree T rooted at r such that S⊂eq V(T) and each vertex of S has degree one in T. Two pendant (S,r)-trees are called internally-disjoint if they are arc-disjoint and their common vertex set is exactly S. The goal of the Internally-disjoint Directed Pendant Steiner Tree Packing (IDPSTP) problem is to find a largest collection of pairwise internally-disjoint pendant (S,r)-trees in D. Let τk(D)=\τS,r(D) S⊂eq V(D),|S|=k,r∈ S\, where τS,r(D) denotes the maximum number of pairwise internally-disjoint pendant (S,r)-trees in D. In this paper, we first completely determine the computational complexity for the decision version of IDPSTP on Eulerian digraphs and symmetric digraphs. We then show that, for any ε>0, given an instance of IDPSTP with order n, it is NP-hard to approximate the solution within O(n1/3-ε). Finally, we get some sharp bounds for the parameter τk(D).