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Variational Bayes for High-Dimensional Linear Regression With Sparse Priors

Kolyan Ray, Botond Szabó

2020Journal of the American Statistical Association56 citationsDOIOpen Access PDF

Abstract

We study a mean-field spike and slab variational Bayes (VB) approximation to Bayesian model selection priors in sparse high-dimensional linear regression. Under compatibility conditions on the design matrix, oracle inequalities are derived for the mean-field VB approximation, implying that it converges to the sparse truth at the optimal rate and gives optimal prediction of the response vector. The empirical performance of our algorithm is studied, showing that it works comparably well as other state-of-the-art Bayesian variable selection methods. We also numerically demonstrate that the widely used coordinate-ascent variational inference algorithm can be highly sensitive to the parameter updating order, leading to potentially poor performance. To mitigate this, we propose a novel prioritized updating scheme that uses a data-driven updating order and performs better in simulations. The variational algorithm is implemented in the R package sparsevb. Supplementary materials for this article are available online.

Topics & Concepts

Prior probabilityBayes' theoremBayesian inferenceMathematicsOracleAlgorithmMathematical optimizationBayesian probabilityInferenceLinear regressionComputer scienceLinear modelBayesian linear regressionModel selectionFeature selectionDesign matrixApplied mathematicsVariable (mathematics)Marginal likelihoodBayesian multivariate linear regressionBayes factorArtificial intelligenceRegressionRegression analysisSelection (genetic algorithm)Random variableMean squared errorFrequentist inferenceGeneralized linear modelLinear programmingGaussian Processes and Bayesian InferenceStochastic Gradient Optimization TechniquesStatistical Methods and Inference