Moderate Dimension Reduction for k-Center Clustering
Abstract
The Johnson-Lindenstrauss (JL) Lemma introduced the concept of dimension reduction via a random linear map, which has become a fundamental technique in many computational settings. For a set of n points in Rd and any fixed ε>0, it reduces the dimension d to O( n) while preserving, with high probability, all the pairwise Euclidean distances within factor 1+ε. Perhaps surprisingly, the target dimension can be lower if one only wishes to preserve the optimal value of a certain problem on the pointset, e.g., Euclidean max-cut or k-means. However, for some notorious problems, like diameter (aka furthest pair), dimension reduction via the JL map to below O( n) does not preserve the optimal value within factor 1+ε. We propose to focus on another regime, of moderate dimension reduction, where a problem's value is preserved within factor α>1 using target dimension n / poly(α). We establish the viability of this approach and show that the famous k-center problem is α-approximated when reducing to dimension O( nα2+ k). Along the way, we address the diameter problem via the special case k=1. Our result extends to several important variants of k-center (with outliers, capacities, or fairness constraints), and the bound improves further with the input's doubling dimension. While our poly(α)-factor improvement in the dimension may seem small, it actually has significant implications for streaming algorithms, and easily yields an algorithm for k-center in dynamic geometric streams, that achieves O(α)-approximation using space poly(kdn1/α2). This is the first algorithm to beat O(n) space in high dimension d, as all previous algorithms require space at least (d). Furthermore, it extends to the k-center variants mentioned above.
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