2021
DOI: 10.1016/j.jcss.2021.06.002
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Polynomial time approximation schemes for clustering in low highway dimension graphs

Abstract: We study clustering problems such as k-Median, k-Means, and Facility Location in graphs of low highway dimension, which is a graph parameter modeling transportation networks. It was previously shown that approximation schemes for these problems exist, which either run in quasi-polynomial time (assuming constant highway dimension) [Feldmann et al. SICOMP 2018] or run in FPT time (parameterized by the number of clusters k, the highway dimension, and the approximation factor) [Becker et al. ESA 2018, Braverman e… Show more

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“…For the k-Median problem parameterized by the doubling dimension, Cohen-Addad et al [13] show an efficient parameterized approximation scheme (EPAS), which is a parameterized algorithm that for some parameter q and any ε > 0 outputs a solution of cost at most (1 + ε)OPT and runs in time O * (f (q, ε)) where f is a computable function. In graphs of constant highway dimension, Feldmann and Saulpic [24] follow up with a polynomial time approximation scheme (PTAS) for k-Median. If we allow k as a parameter as well, then Feldmann and Marx [23] show an EPAS for k-Center in low doubling dimension graphs, while Becker et al [7] show an EPAS for k-Center in low highway dimension graphs.…”
Section: Introductionmentioning
confidence: 99%
“…For the k-Median problem parameterized by the doubling dimension, Cohen-Addad et al [13] show an efficient parameterized approximation scheme (EPAS), which is a parameterized algorithm that for some parameter q and any ε > 0 outputs a solution of cost at most (1 + ε)OPT and runs in time O * (f (q, ε)) where f is a computable function. In graphs of constant highway dimension, Feldmann and Saulpic [24] follow up with a polynomial time approximation scheme (PTAS) for k-Median. If we allow k as a parameter as well, then Feldmann and Marx [23] show an EPAS for k-Center in low doubling dimension graphs, while Becker et al [7] show an EPAS for k-Center in low highway dimension graphs.…”
Section: Introductionmentioning
confidence: 99%