快速和完美的采样子图和聚合物系统

IF 0.9 3区计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS

ACM Transactions on Algorithms Pub Date : 2023-11-10 DOI:10.1145/3632294

Antonio Blanca, Sarah Cannon, Will Perkins

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引用次数: 4

摘要

对有根有界度图的加权连通诱导子图给出了一种高效的完美采样算法。我们的算法利用顶点-渗透过程和精心选择的拒绝过滤器，并在渗透亚临界条件下工作。我们证明了这个条件是最优的，因为对于无限图来说，(近似)抽样加权根图的任务在有限期望时间内是不可能的，而对于有限图来说，当条件不成立时是难以处理的。我们将我们的采样算法作为子程序应用于聚合物模型和有限图中加权无根石墨的近线性时间完美采样算法，这是两个广泛研究但非常不同的问题。这种新的完美的聚合物模型采样算法为低温下自旋系统在膨胀图和不平衡二部图上的采样算法以及其他应用提供了改进。

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Fast and perfect sampling of subgraphs and polymer systems

We give an efficient perfect sampling algorithm for weighted, connected induced subgraphs (or graphlets ) of rooted, bounded degree graphs. Our algorithm utilizes a vertex-percolation process with a carefully chosen rejection filter and works under a percolation subcriticality condition. We show that this condition is optimal in the sense that the task of (approximately) sampling weighted rooted graphlets becomes impossible in finite expected time for infinite graphs and intractable for finite graphs when the condition does not hold. We apply our sampling algorithm as a subroutine to give near linear-time perfect sampling algorithms for polymer models and weighted non-rooted graphlets in finite graphs, two widely studied yet very different problems. This new perfect sampling algorithm for polymer models gives improved sampling algorithms for spin systems at low temperatures on expander graphs and unbalanced bipartite graphs, among other applications.

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来源期刊

ACM Transactions on Algorithms COMPUTER SCIENCE, THEORY & METHODS-MATHEMATICS, APPLIED

CiteScore

3.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： ACM Transactions on Algorithms welcomes submissions of original research of the highest quality dealing with algorithms that are inherently discrete and finite, and having mathematical content in a natural way, either in the objective or in the analysis. Most welcome are new algorithms and data structures, new and improved analyses, and complexity results. Specific areas of computation covered by the journal include combinatorial searches and objects; counting; discrete optimization and approximation; randomization and quantum computation; parallel and distributed computation; algorithms for graphs, geometry, arithmetic, number theory, strings; on-line analysis; cryptography; coding; data compression; learning algorithms; methods of algorithmic analysis; discrete algorithms for application areas such as biology, economics, game theory, communication, computer systems and architecture, hardware design, scientific computing