How to match when all vertices arrive online

Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing Pub Date : 2018-02-12 DOI:10.1145/3188745.3188858

Zhiyi Huang, N. Kang, Zhihao Gavin Tang, Xiaowei Wu, Yuhao Zhang, Xue Zhu

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引用次数: 73

Abstract

We introduce a fully online model of maximum cardinality matching in which all vertices arrive online. On the arrival of a vertex, its incident edges to previously-arrived vertices are revealed. Each vertex has a deadline that is after all its neighbors’ arrivals. If a vertex remains unmatched until its deadline, the algorithm must then irrevocably either match it to an unmatched neighbor, or leave it unmatched. The model generalizes the existing one-sided online model and is motivated by applications including ride-sharing platforms, real-estate agency, etc. We show that the Ranking algorithm by Karp et al. (STOC 1990) is 0.5211-competitive in our fully online model for general graphs. Our analysis brings a novel charging mechanic into the randomized primal dual technique by Devanur et al. (SODA 2013), allowing a vertex other than the two endpoints of a matched edge to share the gain. To our knowledge, this is the first analysis of Ranking that beats 0.5 on general graphs in an online matching problem, a first step towards solving the open problem by Karp et al. (STOC 1990) about the optimality of Ranking on general graphs. If the graph is bipartite, we show that the competitive ratio of Ranking is between 0.5541 and 0.5671. Finally, we prove that the fully online model is strictly harder than the previous model as no online algorithm can be 0.6317 < 1−1/e-competitive in our model even for bipartite graphs.

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如何匹配当所有顶点到达在线

我们引入了一个最大基数匹配的全在线模型，其中所有顶点都在线。当一个顶点到达时，它与先前到达的顶点的关联边被显示出来。每个顶点都有一个截止日期，在所有相邻顶点到达之后。如果一个顶点在截止日期前仍未匹配，那么算法必须不可撤销地将其与未匹配的邻居进行匹配，或者不进行匹配。该模型对现有的片面在线模式进行了概括，并以拼车平台、房产中介等应用为动力。我们表明，Karp等人(STOC 1990)的排名算法在我们对一般图的完全在线模型中具有0.5211的竞争力。我们的分析为Devanur等人(SODA 2013)的随机原始对偶技术引入了一种新的充电机制，允许匹配边的两个端点以外的顶点共享增益。据我们所知，这是第一次在在线匹配问题中对一般图的排名优于0.5的分析，这是解决Karp等人(STOC 1990)关于一般图上排名最优性的开放问题的第一步。如果图是二部图，我们表明排名的竞争比在0.5541 ~ 0.5671之间。最后，我们证明了完全在线模型比之前的模型严格困难，因为在我们的模型中，即使对于二部图，也没有在线算法可以达到0.6317 < 1−1/e竞争。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing

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