# On Approximating Degree-Bounded Network Design Problems

**Authors:** Xiangyu Guo, Guy Kortsarz, Bundit Laekhanukit, Shi Li, Daniel Vaz,, Jiayi Xian

arXiv: 1907.11404 · 2020-04-28

## TL;DR

This paper introduces a quasi-polynomial time bicriteria approximation algorithm for the Degree-Bounded Directed Steiner Tree problem, achieving near-optimal cost guarantees while allowing controlled violations of degree constraints.

## Contribution

It provides the first non-trivial approximation algorithm for the degree-bounded DST problem with explicit degree violation bounds.

## Key findings

- Achieves an $O(	ext{log} n 	ext{log} k)$ cost approximation.
- Violates degree bounds by at most $O(	ext{log}^2 n)$ factor.
- Improves degree violation bounds for the special case of Degree-Bounded Group Steiner Tree on trees.

## Abstract

Directed Steiner Tree (DST) is a central problem in combinatorial optimization and theoretical computer science: Given a directed graph $G=(V, E)$ with edge costs $c \in \mathbb{R}_{\geq 0}^E$, a root $r \in V$ and $k$ terminals $K\subseteq V$, we need to output the minimum-cost arborescence in $G$ that contains an $r$\textrightarrow $t$ path for every $t \in K$. Recently, Grandoni, Laekhanukit and Li, and independently Ghuge and Nagarajan, gave quasi-polynomial time $O(\log^2k/\log \log k)$-approximation algorithms for the problem, which are tight under popular complexity assumptions.   In this paper, we consider the more general Degree-Bounded Directed Steiner Tree (DB-DST) problem, where we are additionally given a degree bound $d_v$ on each vertex $v \in V$, and we require that every vertex $v$ in the output tree has at most $d_v$ children. We give a quasi-polynomial time $(O(\log n \log k), O(\log^2 n))$-bicriteria approximation: The algorithm produces a solution with cost at most $O(\log n\log k)$ times the cost of the optimum solution that violates the degree constraints by at most a factor of $O(\log^2n)$. This is the first non-trivial result for the problem.   While our cost-guarantee is nearly optimal, the degree violation factor of $O(\log^2n)$ is an $O(\log n)$-factor away from the approximation lower bound of $\Omega(\log n)$ from the set-cover hardness. The hardness result holds even on the special case of the {\em Degree-Bounded Group Steiner Tree} problem on trees (DB-GST-T). With the hope of closing the gap, we study the question of whether the degree violation factor can be made tight for this special case. We answer the question in the affirmative by giving an $(O(\log n\log k), O(\log n))$-bicriteria approximation algorithm for DB-GST-T.

## Full text

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## References

24 references — full list in the complete paper: https://tomesphere.com/paper/1907.11404/full.md

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Source: https://tomesphere.com/paper/1907.11404