Polynomial-Time Constant-Approximation for Fair Sum-of-Radii Clustering

April 20, 2025 Β· Declared Dead Β· πŸ› Embedded Systems and Applications

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Authors Sina Bagheri Nezhad, Sayan Bandyapadhyay, Tianzhi Chen arXiv ID 2504.14683 Category cs.DS: Data Structures & Algorithms Citations 2 Venue Embedded Systems and Applications Last Checked 4 months ago
Abstract
In a seminal work, Chierichetti et al. introduced the $(t,k)$-fair clustering problem: Given a set of red points and a set of blue points in a metric space, a clustering is called fair if the number of red points in each cluster is at most $t$ times and at least $1/t$ times the number of blue points in that cluster. The goal is to compute a fair clustering with at most $k$ clusters that optimizes certain objective function. Considering this problem, they designed a polynomial-time $O(1)$- and $O(t)$-approximation for the $k$-center and the $k$-median objective, respectively. Recently, Carta et al. studied this problem with the sum-of-radii objective and obtained a $(6+Ξ΅)$-approximation with running time $O((k\log_{1+Ξ΅}(k/Ξ΅))^kn^{O(1)})$, i.e., fixed-parameter tractable in $k$. Here $n$ is the input size. In this work, we design the first polynomial-time $O(1)$-approximation for $(t,k)$-fair clustering with the sum-of-radii objective, improving the result of Carta et al. Our result places sum-of-radii in the same group of objectives as $k$-center, that admit polynomial-time $O(1)$-approximations. This result also implies a polynomial-time $O(1)$-approximation for the Euclidean version of the problem, for which an $f(k)\cdot n^{O(1)}$-time $(1+Ξ΅)$-approximation was known due to Drexler et al.. Here $f$ is an exponential function of $k$. We are also able to extend our result to any arbitrary $\ell\ge 2$ number of colors when $t=1$. This matches known results for the $k$-center and $k$-median objectives in this case. The significant disparity of sum-of-radii compared to $k$-center and $k$-median presents several complex challenges, all of which we successfully overcome in our work. Our main contribution is a novel cluster-merging-based analysis technique for sum-of-radii that helps us achieve the constant-approximation bounds.
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