{"@context":"https:\/\/schema.org\/","@type":"ScholarlyArticle","@id":"#article8042","name":"How to Tame Rectangles: Solving Independent Set and Coloring of Rectangles via Shrinking","abstract":"In the Maximum Weight Independent Set of Rectangles (MWISR) problem, we are given a collection of weighted axis-parallel rectangles in the plane. Our goal is to compute a maximum weight subset of pairwise non-overlapping rectangles. Due to its various applications, as well as connections to many other problems in computer science, MWISR has received a lot of attention from the computational geometry and the approximation algorithms community. However, despite being extensively studied, MWISR remains not very well understood in terms of polynomial time approximation algorithms, as there is a large gap between the upper and lower bounds, i.e., O(log n\\ loglog n) v.s. NP-hardness. Another important, poorly understood question is whether one can color rectangles with at most O(omega(R)) colors where omega(R) is the size of a maximum clique in the intersection graph of a set of input rectangles R. Asplund and Gr\u00fcnbaum obtained an upper bound of O(omega(R)^2) about 50 years ago, and the result has remained asymptotically best. This question is strongly related to the integrality gap of the canonical LP for MWISR. \r\n\r\nIn this paper, we settle above three open problems in a relaxed model where we are allowed to shrink the rectangles by a tiny bit (rescaling them by a factor of 1-delta for an arbitrarily small constant delta > 0. Namely, in this model, we show (i) a PTAS for MWISR and (ii) a coloring with O(omega(R)) colors which implies a constant upper bound on the integrality gap of the canonical LP. \r\n\r\nFor some applications of MWISR the possibility to shrink the rectangles has a natural, well-motivated meaning. Our results can be seen as an evidence that the shrinking model is a promising way to relax a geometric problem for the purpose of better algorithmic results.","keywords":["Approximation algorithms","independent set","resource augmentation","rectangle intersection graphs","PTAS"],"author":[{"@type":"Person","name":"Adamaszek, Anna","givenName":"Anna","familyName":"Adamaszek"},{"@type":"Person","name":"Chalermsook, Parinya","givenName":"Parinya","familyName":"Chalermsook"},{"@type":"Person","name":"Wiese, Andreas","givenName":"Andreas","familyName":"Wiese"}],"position":3,"pageStart":43,"pageEnd":60,"dateCreated":"2015-08-13","datePublished":"2015-08-13","isAccessibleForFree":true,"license":"https:\/\/creativecommons.org\/licenses\/by\/3.0\/legalcode","copyrightHolder":[{"@type":"Person","name":"Adamaszek, Anna","givenName":"Anna","familyName":"Adamaszek"},{"@type":"Person","name":"Chalermsook, Parinya","givenName":"Parinya","familyName":"Chalermsook"},{"@type":"Person","name":"Wiese, Andreas","givenName":"Andreas","familyName":"Wiese"}],"copyrightYear":"2015","accessMode":"textual","accessModeSufficient":"textual","creativeWorkStatus":"Published","inLanguage":"en-US","sameAs":"https:\/\/doi.org\/10.4230\/LIPIcs.APPROX-RANDOM.2015.43","publisher":"Schloss Dagstuhl \u2013 Leibniz-Zentrum f\u00fcr Informatik","isPartOf":{"@type":"PublicationVolume","@id":"#volume6243","volumeNumber":40,"name":"Approximation, Randomization, and Combinatorial Optimization. Algorithms and Techniques (APPROX\/RANDOM 2015)","dateCreated":"2015-08-13","datePublished":"2015-08-13","editor":[{"@type":"Person","name":"Garg, Naveen","givenName":"Naveen","familyName":"Garg"},{"@type":"Person","name":"Jansen, Klaus","givenName":"Klaus","familyName":"Jansen"},{"@type":"Person","name":"Rao, Anup","givenName":"Anup","familyName":"Rao"},{"@type":"Person","name":"Rolim, Jos\u00e9 D. P.","givenName":"Jos\u00e9 D. P.","familyName":"Rolim"}],"isAccessibleForFree":true,"publisher":"Schloss Dagstuhl \u2013 Leibniz-Zentrum f\u00fcr Informatik","hasPart":"#article8042","isPartOf":{"@type":"Periodical","@id":"#series116","name":"Leibniz International Proceedings in Informatics","issn":"1868-8969","isAccessibleForFree":true,"publisher":"Schloss Dagstuhl \u2013 Leibniz-Zentrum f\u00fcr Informatik","hasPart":"#volume6243"}}}