Almost Tight Approximation Hardness for Single-Source Directed k-Edge-Connectivity

TL;DR

This paper establishes tight approximation hardness results for the single-source directed k-edge-connectivity problem, resolving longstanding open questions and providing bounds that match known algorithms under standard complexity assumptions.

Contribution

It proves new approximation hardness bounds for k-DST, including tight bounds that match existing algorithms, under various complexity hypotheses.

Findings

Hardness of approximation is (|T|/|T|) under NP  ZPP.

Hardness of (\u0010rac{rac{rac{}{k}) for general k.

Hardness of (rac{rac{rac{rac{}{L}) for L-layered graphs.

Abstract

In the $k$-connected directed Steiner tree problem ($k$-DST), we are given an $n$-vertex directed graph $G=(V,E)$ with edge costs, a connectivity requirement $k$, a root $r\in V$ and a set of terminals $T\subseteq V$. The goal is to find a minimum-cost subgraph $H\subseteq G$ that has $k$ internally disjoint paths from the root vertex $r$ to every terminal $t\in T$. In this paper, we show the approximation hardness of $k$-DST for various parameters, which thus close some long-standing open problems. - $\Omega\left(|T|/\log |T|\right)$-approximation hardness, which holds under the standard assumption $\mathrm{NP}\neq \mathrm{ZPP}$. The inapproximability ratio is tightened to $\Omega\left(|T|\right)$ under the Strongish Planted Clique Hypothesis [Manurangsi, Rubinstein and Schramm, ITCS 2021]. The latter hardness result matches the approximation ratio of $|T|$ obtained by a trivial approximation algorithm, thus closing the long-standing open problem. - $\Omega\left(\sqrt{2}^k / k\right)$-approximation hardness for the general case of $k$-DST under the assumption $\mathrm{NP}\neq\mathrm{ZPP}$. This is the first hardness result known for survivable network design problems with an inapproximability ratio exponential in $k$. - $\Omega\left((k/L)^{L/4}\right)$-approximation hardness for $k$-DST on $L$-layered graphs for $L\le O\left(\log n\right)$. This almost matches the approximation ratio of $O(k^{L-1}\cdot L \cdot \log |T|)$ achieving in $O\left(n^L\right)$-time due to Laekhanukit [ICALP`16].