Objective Bayesian Search of Gaussian Directed Acyclic Graphical Models for Ordered Variables with Non‐Local Priors

Altomare, Davide; Consonni, Guido; Rocca, Luca La

doi:10.1111/biom.12018

Cited by 33 publications

(26 citation statements)

References 28 publications

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“…The next result establishes strong selection consistency for the objective non-local prior based approach of [1]. The proof is provided in the Supplementary Document.…”

Section: Results For Non-local Priorsmentioning

confidence: 55%

“…In [1], the authors present an alternative to the Wishart-based Bayesian framework for Gaussian DAG models by using non-local priors. Non-local priors were first introduced in [14] as densities that are identically zero whenever a model parameter is equal to its null value in the context of hypothesis testing (compared to local priors, which still preserve positive values at null parameter values).…”

Section: Results For Non-local Priorsmentioning

confidence: 99%

“…In recent work, Altamore et al [1] develop a class of objective non-local priors for Gaussian DAG models. This class of priors is structurally different from the DAG Wishart priors of [6], and we also investigate posterior model selection consistency under these non-local priors.…”

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confidence: 99%

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Posterior graph selection and estimation consistency for high-dimensional Bayesian DAG models

Cao¹,

Khare²,

Ghosh³

2019

Ann. Statist.

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Covariance estimation and selection for high-dimensional multivariate datasets is a fundamental problem in modern statistics. Gaussian directed acyclic graph (DAG) models are a popular class of models used for this purpose. Gaussian DAG models introduce sparsity in the Cholesky factor of the inverse covariance matrix, and the sparsity pattern in turn corresponds to specific conditional independence assumptions on the underlying variables. A variety of priors have been developed in recent years for Bayesian inference in DAG models, yet crucial convergence and sparsity selection properties for these models have not been thoroughly investigated. Most of these priors are adaptations/generalizations of the Wishart distribution in the DAG context. In this paper, we consider a flexible and general class of these 'DAG-Wishart' priors with multiple shape parameters. Under mild regularity assumptions, we establish strong graph selection consistency and establish posterior convergence rates for estimation when the number of variables p is allowed to grow at an appropriate sub-exponential rate with the sample size n.MSC 2010 subject classifications: Primary 62F15; secondary 62G20 P (|S ij − (Σ 0 ) ij | ≥ t) ≤ m 1 exp{−m 2 n(tǫ 0,n ) 2 }, |t| ≤ δ.

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“…The next result establishes strong selection consistency for the objective non-local prior based approach of [1]. The proof is provided in the Supplementary Document.…”

Section: Results For Non-local Priorsmentioning

confidence: 55%

Section: Results For Non-local Priorsmentioning

confidence: 99%

See 1 more Smart Citation

Posterior graph selection and estimation consistency for high-dimensional Bayesian DAG models

Cao¹,

Khare²,

Ghosh³

2019

Ann. Statist.

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“…In this work we have used a uniform prior on model space for the sake of simplicity and comparison with results obtained using alternative methods. Other choices for priors on model space can be used in conjunction with our method; see for instance Scott and Berger (2010) in the context of variable selection, or Carvalho and Scott (2009) and Altomare et al (2013) for graphical model determination. where α(θ, θ ′ |y) is the acceptance probability of the proposed value and q(θ, θ ′ |y)…”

Section: Discussionmentioning

confidence: 99%

Objective Bayesian Comparison of Constrained Analysis of Variance Models

Consonni

Paroli

2016

Psychometrika

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In the social sciences we are often interested in comparing models specified by parametric equality or inequality constraints. For instance, when examining three group means {µ 1 , µ 2 , µ 3 } through an analysis of variance (ANOVA), a model may specify that µ 1 < µ 2 < µ 3 , while another one may state that {µ 1 = µ 3 } < µ 2 , and finally a third model may instead suggest that all means are unrestricted. This is a challenging problem, because it involves a combination of non-nested models, as well as nested models having the same dimension.We adopt an objective Bayesian approach, and derive the posterior probability of each model under consideration. Our method is based on the intrinsic prior methodology, with suitably modifications to accommodate equality and inequality constraints. Focussing on normal ANOVA models, a comparative assessment is carried out through simulation studies, showing that correct model identification is possible even in situations where frequentist power is low. We also present an application to real data collected in a psychological experiment.

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“…There are recent developments in stochastic search algorithms other than MCMC, including shotgun stochastic search (SSS, Hans et al (2007)) and feature-inclusion stochastic search (FINCS, Scott & Carvalho (2008); Altomare et al (2013)). SSS evaluates many neighboring states (graphs) at each step in parallel and moves to a new state with a probability proportional to its marginal posterior.…”

Section: Bayesian Estimation Of Gaussian Dag Modelsmentioning

confidence: 99%

Nonparametric Bayesian Inference in Biostatistics

Mitra

Müeller²

2015

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We briefly review some of the nonparametric Bayesians models that are most widely used in biostatistics and bioinformatics. We define the Dirichlet process, Dirichlet process mixtures, the Polya tree, the dependent Dirichlet process and the Gaussian process prior. These few models and variations cover a major part of the models that are used in the literature. The discussion includes references to variations of the basic models that are defined in the chapters of this volume.

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Objective Bayesian Search of Gaussian Directed Acyclic Graphical Models for Ordered Variables with Non‐Local Priors

Cited by 33 publications

References 28 publications

Posterior graph selection and estimation consistency for high-dimensional Bayesian DAG models

Posterior graph selection and estimation consistency for high-dimensional Bayesian DAG models

Objective Bayesian Comparison of Constrained Analysis of Variance Models

Nonparametric Bayesian Inference in Biostatistics

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