On the Integrality Gap of Directed Steiner Tree LPs with Relatively Integral Solutions
Abstract
The Directed Steiner Tree (DST) problem is defined on a directed graph G=(V,E), where we are given a designated root vertex r and a set of k terminals K ⊂eq V r. The goal is to find a minimum-cost subgraph that provides directed r → t paths for all terminals t ∈ K. The approximability of DST has long been a central open problem in network design. While there exist polylogarithmic-approximation algorithms with quasi-polynomial running times (Charikar et al. 1998; Grandoni, Laekhanukit, and Li 2019; Ghuge and Nagarajan 2020), the best known polynomial-time approximation until now has remained at kε, for any constant ε > 0. Whether a polynomial-time algorithm achieving a polylogarithmic approximation exists has remained unresolved. In this paper, we present a flow-based LP-relaxation for DST that admits a polylogarithmic integrality gap under the relative integral condition -- there exists a fractional solution in which each edge e either carries a zero flow (fte=0) or uses its full capacity (fte=xe), where fte denotes the flow variable and xe denotes the indicator variable treated as capacities. This stands in contrast to known lower bounds, as the standard flow-based relaxation is known to exhibit a polynomial integrality gap even under relatively integral solutions. In fact, this relatively integral property is shared by all the known integrality gap instances of DST [Halperin~et~al., SODA'07; Zosin-Khuller, SODA'02; Li-Laekhanukit, SODA'22]. We further provide a randomized polynomial-time algorithm that gives an O(3 k)-approximation, assuming access to a relatively integral fractional solution.
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