Regression-Based Bayesian Estimation and Structure Learning for Nonparanormal Graphical Models.

IF 2.1 4区数学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Statistical Analysis and Data Mining Pub Date : 2022-10-01 Epub Date: 2022-02-28 DOI:10.1002/sam.11576

Jami J Mulgrave, Subhashis Ghosal

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Abstract

A nonparanormal graphical model is a semiparametric generalization of a Gaussian graphical model for continuous variables in which it is assumed that the variables follow a Gaussian graphical model only after some unknown smooth monotone transformations. We consider a Bayesian approach to inference in a nonparanormal graphical model in which we put priors on the unknown transformations through a random series based on B-splines. We use a regression formulation to construct the likelihood through the Cholesky decomposition on the underlying precision matrix of the transformed variables and put shrinkage priors on the regression coefficients. We apply a plug-in variational Bayesian algorithm for learning the sparse precision matrix and compare the performance to a posterior Gibbs sampling scheme in a simulation study. We finally apply the proposed methods to a microarray data set. The proposed methods have better performance as the dimension increases, and in particular, the variational Bayesian approach has the potential to speed up the estimation in the Bayesian nonparanormal graphical model without the Gaussianity assumption while retaining the information to construct the graph.

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基于回归的非超自然图形模型贝叶斯估计与结构学习。

非超常图模型是连续变量高斯图模型的半参数推广，其中假设变量仅在经过一些未知的光滑单调变换后才服从高斯图模型。我们考虑在一个非超自然图形模型中使用贝叶斯方法进行推理，在该模型中，我们通过基于b样条的随机序列对未知变换设置先验。我们使用回归公式通过对转换变量的潜在精度矩阵的Cholesky分解来构建似然，并将收缩先验放在回归系数上。我们应用插件变分贝叶斯算法来学习稀疏精度矩阵，并在仿真研究中将其性能与后验吉布斯抽样方案进行比较。最后，我们将提出的方法应用于微阵列数据集。随着维数的增加，所提出的方法具有更好的性能，特别是变分贝叶斯方法在保留构建图的信息的同时，在不考虑高斯性假设的贝叶斯非超常图模型中具有加速估计的潜力。

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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.