## Coresets for Clustering with Fairness Constraints

Part of: Advances in Neural Information Processing Systems 32 (NIPS 2019) pre-proceedings

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### Conference Event Type: Poster

### Abstract

In a recent work, \cite{chierichetti2017fair} studied the following ``fair'' variants of classical clustering problems such as k-means and k-median: given a set of n data points in R^d and a binary type associated to each data point, the goal is to cluster the points while ensuring that the proportion of each type in each cluster is roughly the same as its underlying proportion. Subsequent work has focused on either extending this setting to when each data point has multiple, non-disjoint sensitive types such as race and gender \cite{bera2019fair}, or to address the problem that the clustering algorithms in the above work do not scale well. The main contribution of this paper is an approach to clustering with fairness constraints that involve {\em multiple, non-disjoint} attributes, that is {\em also scalable}. Our approach is based on novel constructions of coresets: for the k-median objective, we construct an \eps-coreset of size O(\Gamma k^2 \eps^{-d}) where \Gamma is the number of distinct collections of groups that a point may belong to, and for the k-means objective, we show how to construct an \eps-coreset of size O(\Gamma k^3\eps^{-d-1}). The former result is the first known coreset construction for the fair clustering problem with the k-median objective, and the latter result removes the dependence on the size of the full dataset as in~\cite{schmidt2018fair} and generalizes it to multiple, non-disjoint attributes. Importantly, plugging our coresets into existing algorithms for fair clustering such as \cite{backurs2019scalable} results in the fastest algorithms for several cases. Empirically, we assess our approach over the \textbf{Adult} and \textbf{Bank} dataset, and show that the coreset sizes are much smaller than the full dataset; applying coresets indeed accelerates the running time of computing the fair clustering objective while ensuring that the resulting objective difference is small.