Multi-scale affinities with missing data: Estimation and applications.

IF 2.1 4区数学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Statistical Analysis and Data Mining Pub Date : 2022-06-01 Epub Date: 2021-11-05 DOI:10.1002/sam.11561

Min Zhang, Gal Mishne, Eric C Chi

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Abstract

Many machine learning algorithms depend on weights that quantify row and column similarities of a data matrix. The choice of weights can dramatically impact the effectiveness of the algorithm. Nonetheless, the problem of choosing weights has arguably not been given enough study. When a data matrix is completely observed, Gaussian kernel affinities can be used to quantify the local similarity between pairs of rows and pairs of columns. Computing weights in the presence of missing data, however, becomes challenging. In this paper, we propose a new method to construct row and column affinities even when data are missing by building off a co-clustering technique. This method takes advantage of solving the optimization problem for multiple pairs of cost parameters and filling in the missing values with increasingly smooth estimates. It exploits the coupled similarity structure among both the rows and columns of a data matrix. We show these affinities can be used to perform tasks such as data imputation, clustering, and matrix completion on graphs.

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有缺失数据的多尺度亲和力：估计与应用

许多机器学习算法都依赖于量化数据矩阵行列相似性的权重。权重的选择会极大地影响算法的有效性。然而，人们对权重选择问题的研究可以说还远远不够。当数据矩阵完全被观测到时，高斯核亲和力可用于量化行对和列对之间的局部相似性。然而，在数据缺失的情况下计算权重就变得非常具有挑战性。在本文中，我们提出了一种新方法，即使在数据缺失的情况下，也能通过协同聚类技术构建行和列亲和力。这种方法利用了解决多对成本参数优化问题的优势，并通过越来越平滑的估计值来填补缺失值。它利用了数据矩阵的行和列之间的耦合相似性结构。我们展示了这些亲和性可用于执行数据估算、聚类和图上矩阵补全等任务。

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来源期刊

Statistical Analysis and Data Mining COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEC-COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

CiteScore

3.20

自引率

7.70%

发文量

期刊介绍： Statistical Analysis and Data Mining addresses the broad area of data analysis, including statistical approaches, machine learning, data mining, and applications. Topics include statistical and computational approaches for analyzing massive and complex datasets, novel statistical and/or machine learning methods and theory, and state-of-the-art applications with high impact. Of special interest are articles that describe innovative analytical techniques, and discuss their application to real problems, in such a way that they are accessible and beneficial to domain experts across science, engineering, and commerce. The focus of the journal is on papers which satisfy one or more of the following criteria: Solve data analysis problems associated with massive, complex datasets Develop innovative statistical approaches, machine learning algorithms, or methods integrating ideas across disciplines, e.g., statistics, computer science, electrical engineering, operation research. Formulate and solve high-impact real-world problems which challenge existing paradigms via new statistical and/or computational models Provide survey to prominent research topics.