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Parameter-expanded data augmentation for analyzing correlated binary data using multivariate probit models.

Xiao Zhang1

  • 1Mathematical Sciences, Michigan Technological University, Houghton, Michigan, USA.

Statistics in Medicine
|July 25, 2020
PubMed
Summary
This summary is machine-generated.

This study introduces efficient parameter-expanded data augmentations for analyzing correlated binary data with multivariate probit models. These methods improve Markov chain convergence and mixing, addressing common Bayesian analysis challenges.

Keywords:
correlated binary datadata augmentationmultivariate probit modelparameter-expanded data augmentation

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Area of Science:

  • Statistics
  • Biostatistics
  • Computational Statistics

Background:

  • Data augmentation is common for analyzing correlated binary data using multivariate probit models in Bayesian analysis.
  • The identification issue in these models requires complex Metropolis-Hastings algorithms, leading to slow convergence and inefficient Markov chains.
  • Parameter-expanded data augmentation can improve mixing and convergence by introducing artificial parameters.

Purpose of the Study:

  • To develop efficient parameter-expanded data augmentation algorithms for multivariate probit models.
  • To investigate both identifiable and non-identifiable multivariate probit models.
  • To improve the convergence and mixing of correlation parameters in Bayesian analysis.

Main Methods:

  • Developed parameter-expanded data augmentation algorithms for both identifiable and non-identifiable multivariate probit models.
  • Applied these methods to analyze correlated binary data.
  • Utilized simulation studies and a real-world longitudinal dataset (Six Cities study) for illustration.

Main Results:

  • Parameter-expanded approaches based on non-identifiable models circumvent the need for a Metropolis-Hastings algorithm for correlation matrix sampling.
  • These methods enhance the convergence and mixing of correlation parameters.
  • The identifiable model approach may yield regression parameters with smaller standard errors compared to the non-identifiable model.

Conclusions:

  • Parameter-expanded data augmentation offers an efficient alternative for analyzing correlated binary data with multivariate probit models.
  • The proposed methods successfully improve computational efficiency and parameter mixing.
  • Both identifiable and non-identifiable model approaches have distinct advantages for specific analytical goals.