平移条件下地球移动距离的精细复杂性

arXiv - CS - Computational Geometry Pub Date : 2024-03-07 DOI:arxiv-2403.04356

Karl Bringmann, Frank Staals, Karol Węgrzycki, Geert van Wordragen

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引用次数: 0

摘要

地球移动距离（Earth Mover's Distance）是计算机科学多个分支中的一种常用相似度量。它测量两个点集之间完全匹配的最小总边长。平移下的地球移动距离（$\mathrm{EMDuT}$）是其平移不变的版本。它在一个点集的所有平移中最小化了地球移动距离。对于 $\mathbb{R}^1$ 中的 $\mathrm{EMDuT}$，我们提出了一种$widetilde{mathcal{O}}(n^2)$-time算法。我们还基于全交向量假说，提出了一个匹配的条件下限，从而证明这个算法几乎是最优的。对于$\mathbb{R}^d$中的$\mathrm{EMDuT}$，我们为$L_1$和$L_\infty$度量提出了一种$\widetilde{mathcal{O}}(n^{2d+2})$-time算法。我们证明了这种对 $d$ 的依赖是渐近紧密的，因为针对 $L_1$ 或 $L_infty$ 的 $n^{o(d)}$ 时算法将与指数时间假说（ETH）相矛盾。在我们的工作之前，人们只知道这些问题的近似计算法。

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Fine-Grained Complexity of Earth Mover's Distance under Translation

The Earth Mover's Distance is a popular similarity measure in several branches of computer science. It measures the minimum total edge length of a perfect matching between two point sets. The Earth Mover's Distance under Translation ($\mathrm{EMDuT}$) is a translation-invariant version thereof. It minimizes the Earth Mover's Distance over all translations of one point set. For $\mathrm{EMDuT}$ in $\mathbb{R}^1$, we present an $\widetilde{\mathcal{O}}(n^2)$-time algorithm. We also show that this algorithm is nearly optimal by presenting a matching conditional lower bound based on the Orthogonal Vectors Hypothesis. For $\mathrm{EMDuT}$ in $\mathbb{R}^d$, we present an $\widetilde{\mathcal{O}}(n^{2d+2})$-time algorithm for the $L_1$ and $L_\infty$ metric. We show that this dependence on $d$ is asymptotically tight, as an $n^{o(d)}$-time algorithm for $L_1$ or $L_\infty$ would contradict the Exponential Time Hypothesis (ETH). Prior to our work, only approximation algorithms were known for these problems.

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arXiv - CS - Computational Geometry

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