The Minimum Enclosing Ball (MEB) problem is one of the most fundamental problems in clustering, with applications in operations research, statistics and computational geometry. In this works, we give the first differentially private (DP) fPTAS for the Minimum Enclosing Ball problem, improving both on the runtime and the utility bound of the best known DP-PTAS for the problem, of Ghazi et al. (2020). Given $n$ points in $\R^d$ that are covered by the ball $B(\theta_{opt},r_{opt})$, our simple iterative DP-algorithm returns a ball $B(\theta,r)$ where $r\leq (1+\gamma)r_{opt}$ and which leaves at most $\tilde O(\frac{\sqrt d}{\gamma\epsilon})$ points uncovered in $\tilde O(\nicefrac n {\gamma^2})$-time. We also give a local-model version of our algorithm, that leaves at most $\tilde O(\frac{\sqrt {nd}}{\gamma\epsilon})$ points uncovered, improving on the $n^{0.67}$-bound of Nissim and Stemmer (2018) (at the expense of other parameters). In addition, we test our algorithm empirically and discuss future open problems.
翻译:最小封闭球问题(MEB) 是分组的最根本问题之一, 包括业务研究、 统计和计算几何中的应用。 在这项工作中, 我们给出了第一个用于最小封闭球问题的有差别的私人( DP) FPTAS( DP) FPTAS( DP), 在运行时间和最著名的DP- PTAS( Ghazi et al. (220) ) 的实用约束下, 改善运行时间和最佳已知DP- PTAS( 2020) 。 鉴于美元( 美元) 美元( 美元) 被球( (\\ teta ⁇ opt} ) 覆盖在 $( ) ( ) 美元( ) 美元) ( 美元) 开放的, r\ opt} 我们简单的 DDP- algoithm 返回一个 美元 (\ ) 美元 (theta,r) $( tata, r) $ ( ) $ ( ) $( gammama) r) r) $( ) ( Surmax) ( r) ( lex) ( ) ( lex) ( ) ( lex) ( ) ( ) ( lex) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) (美元) (美元) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) (美元) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) (美元) ( ) (美元) (美元) (美元) (美元) ( ) (美元) (美元) (美元) (美元) (美元) (美元) (美元) (美元) ) (美元) (美元) (美元) (美元) (美元) (美元) ) (美元) (美元) (美元) (美元) (美元) (美元) (美元) (美元) (美元) (美元) (
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