Fast Bayesian Factor Analysis via Automatic Rotations to Sparsity

Ročková, Veronika; George, Edward I.

doi:10.1080/01621459.2015.1100620

Cited by 94 publications

(156 citation statements)

References 39 publications

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“…For comparison, we implemented inference also under the sparse latent factor model (SLFM, Ročková & George 2016) to { Z, Y }. SLFM assumes a sparse loading matrix and unstructured latent factors.…”

Section: Simulation Studymentioning

confidence: 99%

“…Latent factor models assume that the variables are continuous and follow independent normal distributions centered on latent factors multiplied by factor loadings. Imposing sparsity constraints (Bhattacharya & Dunson, 2011;Ročková & George, 2016), latent factor models can be potentially adopted for the discovery of latent causes. However, the assumptions of normality and linear structure are often violated in practice and it is not straightforward to incorporate known diagnostic information into latent factor models.…”

Section: Introductionmentioning

confidence: 99%

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Bayesian Double Feature Allocation for Phenotyping With Electronic Health Records

Müller

2019

Journal of the American Statistical Association

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We propose a categorical matrix factorization method to infer latent diseases from electronic health records (EHR) data in an unsupervised manner. A latent disease is defined as an unknown biological aberration that causes a set of common symptoms for a group of patients. The proposed approach is based on a novel double feature allocation model which simultaneously allocates features to the rows and the columns of a categorical matrix. Using a Bayesian approach, available prior information on known diseases greatly improves identifiability and interpretability of latent diseases. This includes known diagnoses for patients and known association of diseases with symptoms. We validate the proposed approach by simulation studies including misspecified models and comparison with sparse latent factor models. In the application to Chinese EHR data, we find interesting results, some of which agree with related clinical and medical knowledge.

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Section: Simulation Studymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bayesian Double Feature Allocation for Phenotyping With Electronic Health Records

Müller

2019

Journal of the American Statistical Association

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“…Importantly, the latter authors assume that every observed variable has a nonzero loading associated with only one latent trait; this assumption is restrictive and results in a model that, using the definitions in this paper, would be called "confirmatory" instead of "exploratory." Finally, Rocková and George (2014) propose an alternative method whereby m is set to a large value, and "spike-and-slab" priors are used to enforce simplicity of the matrix. These prior distributions fix weak loadings to zero, so that smaller values of m are obtained by fixing to zero all loadings associated with a latent trait.…”

Section: Discussionmentioning

confidence: 99%

Bayesian latent variable models for the analysis of experimental psychology data

Merkle

Wang

2016

Psychon Bull Rev

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In this paper, we address the use of Bayesian factor analysis and structural equation models to draw inferences from experimental psychology data. While such application is non-standard, the models are generally useful for the unified analysis of multivariate data that stem from, e.g., subjects' responses to multiple experimental stimuli. We first review the models and the parameter identification issues inherent in the models. We then provide details on model estimation via JAGS and on Bayes factor estimation. Finally, we use the models to re-analyze experimental data on risky choice, comparing the approach to simpler, alternative methods. Keywords Bayesian statistics · Decision makingTraditional applications of factor analysis and related latent variable models include psychometric scale development, analysis of observational data, and possibly data reduction (though the related, but distinct, principal components

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“…One of the most commonly used assumptions to remedy this issue is to assume that the precision matrix is sparse, i.e., a large majority of its entries are zero (Dempster, 1972), which turns out to be quite useful in practice in the aforementioned GGM owing to its interpretability. Another possibility is to assume a sparse structure on the covariance matrix through, for example, a sparse factor model (Carvalho et al, 2008;Fan et al, 2008Fan et al, , 2011Bühlmann and Van De Geer, 2011;Pourahmadi, 2013;Ročková and George, 2016a), to obtain a sparse covariance matrix estimator, and invert it to estimate the precision matrix. However, the precision matrix estimator obtained from this strategy is not guaranteed to be sparse, which is important for interpretability in our context.…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, we propose a new Bayesian approach for estimation and structure recovery for GGMs. Specifically, to achieve adaptive shrinkage, we model the off-diagonal elements of Θ using a continuous spike-and-slab prior with a mixture of two Laplace distributions, which is known as the spike-and-slab Lasso prior in Ročková (2016), Ročková and George (2016a) and Ročková and George (2016b). Continuous spike-and-slab priors are commonly used for high dimensional regression (George and McCulloch, 1993;Ishwaran and Rao, 2005;Narisetty and He, 2014) and a Gibbs sampling algorithm is often used for posterior computation.…”

Section: Introductionmentioning

confidence: 99%

Bayesian Regularization for Graphical Models With Unequal Shrinkage

Gan

Narisetty

Liang

2018

Journal of the American Statistical Association

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We consider a Bayesian framework for estimating a high-dimensional sparse precision matrix, in which adaptive shrinkage and sparsity are induced by a mixture of Laplace priors. Besides discussing our formulation from the Bayesian standpoint, we investigate the MAP (maximum a posteriori) estimator from a penalized likelihood perspective that gives rise to a new non-convex penalty approximating the 0 penalty.Optimal error rates for estimation consistency in terms of various matrix norms along with selection consistency for sparse structure recovery are shown for the unique MAP estimator under mild conditions. For fast and efficient computation, an EM algorithm is proposed to compute the MAP estimator of the precision matrix and (approximate) posterior probabilities on the edges of the underlying sparse structure.Through extensive simulation studies and a real application to a call center data, we have demonstrated the fine performance of our method compared with existing alternatives.

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Fast Bayesian Factor Analysis via Automatic Rotations to Sparsity

Cited by 94 publications

References 39 publications

Bayesian Double Feature Allocation for Phenotyping With Electronic Health Records

Bayesian Double Feature Allocation for Phenotyping With Electronic Health Records

Bayesian latent variable models for the analysis of experimental psychology data

Bayesian Regularization for Graphical Models With Unequal Shrinkage

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