Minimum Spanning Trees with Bounded Degrees of Vertices in a Specified Stable Set

Abstract

Given a graph G and sets \αv~|~v ∈ V(G)\ and \βv~|~v ∈ V(G)\ of non-negative integers, it is known that the decision problem whether G contains a spanning tree T such that αv dT (v) βv for all v ∈ V(G) is NP-complete. In this article, we relax the problem by demanding that the degree restrictions apply to vertices v∈ U only, where U is a stable set of G. In this case, the problem becomes tractable. A. Frank presented a result characterizing the positive instances of that relaxed problem. Using matroid intersection developed by J. Edmonds, we give a new and short proof of Frank's result and show that if U is stable and the edges of G are weighted by arbitrary real numbers, then even a minimum-cost tree T with αv dT (v) βv for all v ∈ U can be found in polynomial time if such a tree exists.