{"title":"Computing Instance-Optimal Kernels in Two Dimensions","authors":"Pankaj K. Agarwal, Sariel Har-Peled","doi":"10.1007/s00454-024-00637-x","DOIUrl":null,"url":null,"abstract":"<p>Let <span>\\(P\\)</span> be a set of <i>n</i> points in <span>\\(\\mathbb {R}^2\\)</span>. For a parameter <span>\\(\\varepsilon \\in (0,1)\\)</span>, a subset <span>\\(C\\subseteq P\\)</span> is an <span>\\(\\varepsilon \\)</span>-<i>kernel</i> of <span>\\(P\\)</span> if the projection of the convex hull of <span>\\(C\\)</span> approximates that of <span>\\(P\\)</span> within <span>\\((1-\\varepsilon )\\)</span>-factor in every direction. The set <span>\\(C\\)</span> is a <i>weak</i> <span>\\(\\varepsilon \\)</span><i>-kernel</i> of <span>\\(P\\)</span> if its directional width approximates that of <span>\\(P\\)</span> in every direction. Let <span>\\(\\textsf{k}_{\\varepsilon }(P)\\)</span> (resp. <span>\\(\\textsf{k}^{\\textsf{w}}_{\\varepsilon }(P)\\)</span>) denote the minimum-size of an <span>\\(\\varepsilon \\)</span>-kernel (resp. weak <span>\\(\\varepsilon \\)</span>-kernel) of <span>\\(P\\)</span>. We present an <span>\\(O(n\\textsf{k}_{\\varepsilon }(P)\\log n)\\)</span>-time algorithm for computing an <span>\\(\\varepsilon \\)</span>-kernel of <span>\\(P\\)</span> of size <span>\\(\\textsf{k}_{\\varepsilon }(P)\\)</span>, and an <span>\\(O(n^2\\log n)\\)</span>-time algorithm for computing a weak <span>\\(\\varepsilon \\)</span>-kernel of <span>\\(P\\)</span> of size <span>\\(\\textsf{k}^{\\textsf{w}}_{\\varepsilon }(P)\\)</span>. We also present a fast algorithm for the Hausdorff variant of this problem. In addition, we introduce the notion of <span>\\(\\varepsilon \\)</span>-<i>core</i>, a convex polygon lying inside , prove that it is a good approximation of the optimal <span>\\(\\varepsilon \\)</span>-kernel, present an efficient algorithm for computing it, and use it to compute an <span>\\(\\varepsilon \\)</span>-kernel of small size.</p>","PeriodicalId":50574,"journal":{"name":"Discrete & Computational Geometry","volume":"247 1","pages":""},"PeriodicalIF":0.6000,"publicationDate":"2024-04-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Discrete & Computational Geometry","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1007/s00454-024-00637-x","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"COMPUTER SCIENCE, THEORY & METHODS","Score":null,"Total":0}
引用次数: 0
Abstract
Let \(P\) be a set of n points in \(\mathbb {R}^2\). For a parameter \(\varepsilon \in (0,1)\), a subset \(C\subseteq P\) is an \(\varepsilon \)-kernel of \(P\) if the projection of the convex hull of \(C\) approximates that of \(P\) within \((1-\varepsilon )\)-factor in every direction. The set \(C\) is a weak\(\varepsilon \)-kernel of \(P\) if its directional width approximates that of \(P\) in every direction. Let \(\textsf{k}_{\varepsilon }(P)\) (resp. \(\textsf{k}^{\textsf{w}}_{\varepsilon }(P)\)) denote the minimum-size of an \(\varepsilon \)-kernel (resp. weak \(\varepsilon \)-kernel) of \(P\). We present an \(O(n\textsf{k}_{\varepsilon }(P)\log n)\)-time algorithm for computing an \(\varepsilon \)-kernel of \(P\) of size \(\textsf{k}_{\varepsilon }(P)\), and an \(O(n^2\log n)\)-time algorithm for computing a weak \(\varepsilon \)-kernel of \(P\) of size \(\textsf{k}^{\textsf{w}}_{\varepsilon }(P)\). We also present a fast algorithm for the Hausdorff variant of this problem. In addition, we introduce the notion of \(\varepsilon \)-core, a convex polygon lying inside , prove that it is a good approximation of the optimal \(\varepsilon \)-kernel, present an efficient algorithm for computing it, and use it to compute an \(\varepsilon \)-kernel of small size.
期刊介绍:
Discrete & Computational Geometry (DCG) is an international journal of mathematics and computer science, covering a broad range of topics in which geometry plays a fundamental role. It publishes papers on such topics as configurations and arrangements, spatial subdivision, packing, covering, and tiling, geometric complexity, polytopes, point location, geometric probability, geometric range searching, combinatorial and computational topology, probabilistic techniques in computational geometry, geometric graphs, geometry of numbers, and motion planning.