Internally-disjoint directed pendant Steiner trees with three terminal vertices in Cartesian product digraphs

Abstract

Let D=(V(D),A(D)) be a digraph with a terminal vertex subset S⊂eq V(D) such that |S|=k≥ 2. An out-tree T of D rooted at r is called a directed pendant (S,r)-Steiner tree (or, pendant (S,r)-tree for short) if r∈ S⊂eq V(T) and dT+(r)=dT-(u)=1 for each u∈ S \r\. Two pendant (S,r)-trees T1 and T2 are internally-disjoint if A(T1) A(T2)= and V(T1) V(T2)=S. The pendant-tree k-connectivity τk(D) of D is defined as 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 derive a sharp lower bound for the pendant-tree 3-connectivity of the Cartesian product digraph D H, where D and H are both strong digraphs. Specifically, we prove the lower bound τ3(D H)≥ τ3(D)+τ3(H). Moreover, we propose a polynomial-time algorithm for finding internally-disjoint pendant (S,r)-trees which attain this lower bound.