Parameterized Approximation for Robust Clustering in Discrete Geometric Spaces
May 12, 2023 Β· Declared Dead Β· π International Colloquium on Automata, Languages and Programming
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Authors
Fateme Abbasi, Sandip Banerjee, JarosΕaw Byrka, Parinya Chalermsook, Ameet Gadekar, Kamyar Khodamoradi, DΓ‘niel Marx, Roohani Sharma, Joachim Spoerhase
arXiv ID
2305.07316
Category
cs.DS: Data Structures & Algorithms
Cross-listed
cs.CG,
cs.LG
Citations
6
Venue
International Colloquium on Automata, Languages and Programming
Last Checked
4 months ago
Abstract
We consider the well-studied Robust $(k, z)$-Clustering problem, which generalizes the classic $k$-Median, $k$-Means, and $k$-Center problems. Given a constant $z\ge 1$, the input to Robust $(k, z)$-Clustering is a set $P$ of $n$ weighted points in a metric space $(M,Ξ΄)$ and a positive integer $k$. Further, each point belongs to one (or more) of the $m$ many different groups $S_1,S_2,\ldots,S_m$. Our goal is to find a set $X$ of $k$ centers such that $\max_{i \in [m]} \sum_{p \in S_i} w(p) Ξ΄(p,X)^z$ is minimized. This problem arises in the domains of robust optimization [Anthony, Goyal, Gupta, Nagarajan, Math. Oper. Res. 2010] and in algorithmic fairness. For polynomial time computation, an approximation factor of $O(\log m/\log\log m)$ is known [Makarychev, Vakilian, COLT $2021$], which is tight under a plausible complexity assumption even in the line metrics. For FPT time, there is a $(3^z+Ξ΅)$-approximation algorithm, which is tight under GAP-ETH [Goyal, Jaiswal, Inf. Proc. Letters, 2023]. Motivated by the tight lower bounds for general discrete metrics, we focus on \emph{geometric} spaces such as the (discrete) high-dimensional Euclidean setting and metrics of low doubling dimension, which play an important role in data analysis applications. First, for a universal constant $Ξ·_0 >0.0006$, we devise a $3^z(1-Ξ·_{0})$-factor FPT approximation algorithm for discrete high-dimensional Euclidean spaces thereby bypassing the lower bound for general metrics. We complement this result by showing that even the special case of $k$-Center in dimension $Ξ(\log n)$ is $(\sqrt{3/2}- o(1))$-hard to approximate for FPT algorithms. Finally, we complete the FPT approximation landscape by designing an FPT $(1+Ξ΅)$-approximation scheme (EPAS) for the metric of sub-logarithmic doubling dimension.
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