Tight FPT Approximation for Socially Fair Clustering

Inf. Process. Lett. Pub Date : 2021-06-12 DOI:10.2139/ssrn.4226483

Dishant Goyal, Ragesh Jaiswal

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引用次数: 6

Abstract

In this work, we study the socially fair $k$-median/$k$-means problem. We are given a set of points $P$ in a metric space $\mathcal{X}$ with a distance function $d(.,.)$. There are $\ell$ groups: $P_1,\dotsc,P_{\ell} \subseteq P$. We are also given a set $F$ of feasible centers in $\mathcal{X}$. The goal in the socially fair $k$-median problem is to find a set $C \subseteq F$ of $k$ centers that minimizes the maximum average cost over all the groups. That is, find $C$ that minimizes the objective function $\Phi(C,P) \equiv \max_{j} \Big\{ \sum_{x \in P_j} d(C,x)/|P_j| \Big\}$, where $d(C,x)$ is the distance of $x$ to the closest center in $C$. The socially fair $k$-means problem is defined similarly by using squared distances, i.e., $d^{2}(.,.)$ instead of $d(.,.)$. The current best approximation guarantee for both the problems is $O\left( \frac{\log \ell}{\log \log \ell} \right)$ due to Makarychev and Vakilian [COLT 2021]. In this work, we study the fixed parameter tractability of the problems with respect to parameter $k$. We design $(3+\varepsilon)$ and $(9 + \varepsilon)$ approximation algorithms for the socially fair $k$-median and $k$-means problems, respectively, in FPT (fixed parameter tractable) time $f(k,\varepsilon) \cdot n^{O(1)}$, where $f(k,\varepsilon) = (k/\varepsilon)^{{O}(k)}$ and $n = |P \cup F|$. Furthermore, we show that if Gap-ETH holds, then better approximation guarantees are not possible in FPT time.

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社会公平聚类的严格FPT近似

在这项工作中，我们研究了社会公平$k$ -中位数/ $k$ -均值问题。我们在度量空间$\mathcal{X}$中给定一组点$P$，其距离函数为$d(.,.)$。有$\ell$组:$P_1,\dotsc,P_{\ell} \subseteq P$。并给出了$\mathcal{X}$中可行中心的一组$F$。社会公平$k$ -中值问题的目标是找到一组$C \subseteq F$的$k$中心，使所有群体的最大平均成本最小化。也就是说，找到最小化目标函数$\Phi(C,P) \equiv \max_{j} \Big\{ \sum_{x \in P_j} d(C,x)/|P_j| \Big\}$的$C$，其中$d(C,x)$是$x$到$C$中最近的中心的距离。社会公平$k$ -均值问题同样通过使用平方距离来定义，即$d^{2}(.,.)$而不是$d(.,.)$。目前这两个问题的最佳近似保证是$O\left( \frac{\log \ell}{\log \log \ell} \right)$，这是由Makarychev和Vakilian提出的[COLT 2021]。在这项工作中，我们研究了关于参数$k$的问题的固定参数可跟踪性。在FPT(固定参数可处理)时间$f(k,\varepsilon) \cdot n^{O(1)}$，我们分别为社会公平的$k$ -中位数和$k$ -均值问题设计了$(3+\varepsilon)$和$(9 + \varepsilon)$近似算法，其中$f(k,\varepsilon) = (k/\varepsilon)^{{O}(k)}$和$n = |P \cup F|$。进一步，我们证明了如果Gap-ETH成立，那么在FPT时间内不可能有更好的近似保证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Inf. Process. Lett.

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