Approximating (k,)-center clustering for curves

Abstract

The Euclidean k-center problem is a classical problem that has been extensively studied in computer science. Given a set G of n points in Euclidean space, the problem is to determine a set C of k centers (not necessarily part of G) such that the maximum distance between a point in G and its nearest neighbor in C is minimized. In this paper we study the corresponding (k,)-center problem for polygonal curves under the Fr\'echet distance, that is, given a set G of n polygonal curves in R^d, each of complexity m, determine a set C of k polygonal curves in R^d, each of complexity , such that the maximum Fr\'echet distance of a curve in G to its closest curve in C is minimized. In this paper, we substantially extend and improve the known approximation bounds for curves in dimension 2 and higher. We show that, if is part of the input, then there is no polynomial-time approximation scheme unless P=NP. Our constructions yield different bounds for one and two-dimensional curves and the discrete and continuous Fr\'echet distance. In the case of the discrete Fr\'echet distance on two-dimensional curves, we show hardness of approximation within a factor close to 2.598. This result also holds when k=1, and the NP-hardness extends to the case that =, i.e., for the problem of computing the minimum-enclosing ball under the Fr\'echet distance. Finally, we observe that a careful adaptation of Gonzalez' algorithm in combination with a curve simplification yields a 3-approximation in any dimension, provided that an optimal simplification can be computed exactly. We conclude that our approximation bounds are close to being tight.

Tasks

Reproductions