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Main Authors: Lee, Euiwoong, Shin, Kijun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.18105
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author Lee, Euiwoong
Shin, Kijun
author_facet Lee, Euiwoong
Shin, Kijun
contents Recent years have seen great progress in the approximability of fundamental clustering and facility location problems on high-dimensional Euclidean spaces, including $k$-Means and $k$-Median. While they admit strictly better approximation ratios than their general metric versions, their approximation ratios are still higher than the hardness ratios for general metrics, leaving the possibility that the ultimate optimal approximation ratios will be the same between Euclidean and general metrics. Moreover, such an improved algorithm for Euclidean spaces is not known for Uncapaciated Facility Location (UFL), another fundamental problem in the area. In this paper, we prove that for any $γ\geq 1.6774$ there exists $\varepsilon > 0$ such that Euclidean UFL admits a $(γ, 1 + 2e^{-γ} - \varepsilon)$-bifactor approximation algorithm, improving the result of Byrka and Aardal. Together with the $(γ, 1 + 2e^{-γ})$ NP-hardness in general metrics, it shows the first separation between general and Euclidean metrics for the aforementioned basic problems. We also present an $(α_{Li} - \varepsilon)$-(unifactor) approximation algorithm for UFL for some $\varepsilon > 0$ in Euclidean spaces, where $α_{Li} \approx 1.488$ is the best-known approximation ratio for UFL by Li.
format Preprint
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publishDate 2025
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spellingShingle Facility Location on High-dimensional Euclidean Spaces
Lee, Euiwoong
Shin, Kijun
Data Structures and Algorithms
Recent years have seen great progress in the approximability of fundamental clustering and facility location problems on high-dimensional Euclidean spaces, including $k$-Means and $k$-Median. While they admit strictly better approximation ratios than their general metric versions, their approximation ratios are still higher than the hardness ratios for general metrics, leaving the possibility that the ultimate optimal approximation ratios will be the same between Euclidean and general metrics. Moreover, such an improved algorithm for Euclidean spaces is not known for Uncapaciated Facility Location (UFL), another fundamental problem in the area. In this paper, we prove that for any $γ\geq 1.6774$ there exists $\varepsilon > 0$ such that Euclidean UFL admits a $(γ, 1 + 2e^{-γ} - \varepsilon)$-bifactor approximation algorithm, improving the result of Byrka and Aardal. Together with the $(γ, 1 + 2e^{-γ})$ NP-hardness in general metrics, it shows the first separation between general and Euclidean metrics for the aforementioned basic problems. We also present an $(α_{Li} - \varepsilon)$-(unifactor) approximation algorithm for UFL for some $\varepsilon > 0$ in Euclidean spaces, where $α_{Li} \approx 1.488$ is the best-known approximation ratio for UFL by Li.
title Facility Location on High-dimensional Euclidean Spaces
topic Data Structures and Algorithms
url https://arxiv.org/abs/2501.18105