Tight analysis of the primal-dual method for edge-covering pliable set families
April 04, 2025 Β· Declared Dead Β· π International Symposium on Mathematical Foundations of Computer Science
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Authors
Zeev Nutov
arXiv ID
2504.03910
Category
cs.DS: Data Structures & Algorithms
Citations
5
Venue
International Symposium on Mathematical Foundations of Computer Science
Last Checked
4 months ago
Abstract
A classic result of Williamson, Goemans, Mihail, and Vazirani [STOC 1993: 708-717] states that the problem of covering an uncrossable set family by a min-cost edge set admits approximation ratio $2$, by a primal-dual algorithm with a reverse delete phase. Bansal, Cheriyan, Grout, and Ibrahimpur [ICALP 2023: 15:1-15:19] showed that this algorithm achieves approximation ratio $16$ for a larger class of so called $Ξ³$-pliable set families, that have much weaker uncrossing properties. The approximation ratio $16$ was improved to $10$ by the author [WAOA 2025: 151-166]. Recently, Bansal [arXiv:2308.15714] stated approximation ratio $8$ for $Ξ³$-pliable families and an improved approximation ratio $5$ for an important particular case of the family of cuts of size $<k$ of a graph $H$, but his proof has an error. We will improve the approximation ratio to $7$ for the former case and give a simple proof of approximation ratio $6$ for the latter case. Furthermore, if $H$ is $Ξ»$-edge-connected then we will show a slightly better approximation ratio $6-\frac{1}{Ξ²+1}$, where $Ξ²=\left\lfloor\frac{k-1}{\lceil(Ξ»+1)/2\rceil}\right\rfloor$. Our analysis is supplemented by examples showing that these approximation ratios are tight for the primal-dual algorithm.
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