Near-Optimal Dimension Reduction for Facility Location

November 08, 2024 Β· Declared Dead Β· πŸ› Symposium on the Theory of Computing

πŸ‘» CAUSE OF DEATH: Ghosted
No code link whatsoever

"No code URL or promise found in abstract"

Evidence collected by the PWNC Scanner

Authors Lingxiao Huang, Shaofeng H. -C. Jiang, Robert Krauthgamer, Di Yue arXiv ID 2411.05432 Category cs.DS: Data Structures & Algorithms Citations 3 Venue Symposium on the Theory of Computing Last Checked 4 months ago
Abstract
Oblivious dimension reduction, Γ  la the Johnson-Lindenstrauss (JL) Lemma, is a fundamental approach for processing high-dimensional data. We study this approach for Uniform Facility Location (UFL) on a Euclidean input $X\subset\mathbb{R}^d$, where facilities can lie in the ambient space (not restricted to $X$). Our main result is that target dimension $m=\tilde{O}(Ξ΅^{-2}\mathrm{ddim})$ suffices to $(1+Ξ΅)$-approximate the optimal value of UFL on inputs whose doubling dimension is bounded by $\mathrm{ddim}$. It significantly improves over previous results, that could only achieve $O(1)$-approximation [Narayanan, Silwal, Indyk, and Zamir, ICML 2021] or dimension $m=O(Ξ΅^{-2}\log n)$ for $n=|X|$, which follows from [Makarychev, Makarychev, and Razenshteyn, STOC 2019]. Our oblivious dimension reduction has immediate implications to streaming and offline algorithms, by employing known algorithms for low dimension. In dynamic geometric streams, it implies a $(1+Ξ΅)$-approximation algorithm that uses $O(Ξ΅^{-1}\log n)^{\tilde{O}(\mathrm{ddim}/Ξ΅^{2})}$ bits of space, which is the first streaming algorithm for UFL to utilize the doubling dimension. In the offline setting, it implies a $(1+Ξ΅)$-approximation algorithm, which we further refine to run in time $( (1/Ξ΅)^{\tilde{O}(\mathrm{ddim})} d + 2^{(1/Ξ΅)^{\tilde{O}(\mathrm{ddim})}}) \cdot \tilde{O}(n) $. Prior work has a similar running time but requires some restriction on the facilities [Cohen-Addad, Feldmann and Saulpic, JACM 2021]. Our main technical contribution is a fast procedure to decompose an input $X$ into several $k$-median instances for small $k$. This decomposition is inspired by, but has several significant differences from [Czumaj, Lammersen, Monemizadeh and Sohler, SODA 2013], and is key to both our dimension reduction and our PTAS.
Community shame:
Not yet rated
Community Contributions

Found the code? Know the venue? Think something is wrong? Let us know!

πŸ“œ Similar Papers

In the same crypt β€” Data Structures & Algorithms

Died the same way β€” πŸ‘» Ghosted