Massively Parallel and Dynamic Algorithms for Minimum Size Clustering

In this paper, we study the $r$-gather problem, a natural formulation of minimum-size clustering in metric spaces. The goal of $r$-gather is to partition $n$ points into clusters such that each cluster has size at least $r$, and the maximum radius of the clusters is minimized. This additional constraint completely changes the algorithmic nature of the problem, and many clustering techniques fail. Also previous dynamic and parallel algorithms do not achieve desirable complexity. We propose algorithms both in the Massively Parallel Computation (MPC) model and in the dynamic setting. Our MPC algorithm handles input points from the Euclidean space $\mathbb{R}^d$. It computes an $O(1)$-approximate solution of $r$-gather in $O(\log^{{\varepsilon}} n)$ rounds using total space $O(n^{{1+\gamma}\cdot} d)$ for arbitrarily small constants $\varepsilon,\gamma > 0$. In addition our algorithm is fully scalable, i.e., there is no lower bound on the memory per machine. Our dynamic algorithm maintains an $O(1)$-approximate $r$-gather solution under insertions/deletions of points in a metric space with doubling dimension $d$. The update time is $r \cdot 2^{O(d)}\cdot \log^{{O(1)}\Delta$} and the query time is $2^{O(d)}\cdot \log^{{O(1)}\Delta$,} where $\Delta$ is the ratio between the largest and the smallest distance.