On the Tree Augmentation Problem

Abstract

In the Tree Augmentation problem we are given a tree T=(V,F) and a set E ⊂eq V × V of edges with positive integer costs \ce:e ∈ E\. The goal is to augment T by a minimum cost edge set J ⊂eq E such that T J is 2-edge-connected. We obtain the following results. Recently, Adjiashvili [SODA 17] introduced a novel LP for the problem and used it to break the 2-approximation barrier for instances when the maximum cost M of an edge in E is bounded by a constant; his algorithm computes a 1.96418+ε approximate solution in time n(M/ε2)O(1). Using a simpler LP, we achieve ratio 127+ε in time 2O(M/ε2) poly(n).This gives ratio better than 2 for logarithmic costs, and not only for constant costs. One of the oldest open questions for the problem is whether for unit costs (when M=1) the standard LP-relaxation, so called Cut-LP, has integrality gap less than 2. We resolve this open question by proving that for unit costs the integrality gap of the Cut-LP is at most 28/15=2-2/15. In addition, we will prove that another natural LP-relaxation, that is much simpler than the ones in previous work, has integrality gap at most 7/4.