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A new Bayesian Covariance Structure Model (BCSM) models complex dependencies in response times without random effects. This approach improves accuracy for small variance parameters and enhances model selection for digital assessments.

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Area of Science:

  • Psychometrics
  • Statistical Modeling
  • Bayesian Inference

Background:

  • Traditional log-normal models for response times struggle with complex dependencies.
  • Existing Bayesian frameworks often rely on random-effect variables, which can complicate modeling.

Purpose of the Study:

  • To propose a novel Bayesian Covariance Structure Model (BCSM) for multivariate response times.
  • To model complex dependencies directly through an additive covariance structure, avoiding explicit random effects.
  • To develop conjugate priors for variance parameters that facilitate model testing and accurate estimation.

Main Methods:

  • Developed a Bayesian Covariance Structure Model (BCSM) with an additive covariance structure.
  • Proposed a class of conjugate priors for random-effect variance parameters.
  • Utilized Markov Chain Monte Carlo (MCMC) algorithms for posterior computation.
  • Employed Bayes factors and Bayesian Information Criterion for model selection.

Main Results:

  • The BCSM effectively models complex dependencies in response times, such as those arising from testlets or time limits.
  • Conjugate priors support testing for random effects and allow for non-positive (co)variance parameters, reducing boundary issues.
  • The MCMC algorithm and Bayes factor demonstrated satisfactory performance in simulation studies.
  • Estimates of near-zero variance parameters were unbiased, and credible interval undercoverage was avoided compared to alternative methods.

Conclusions:

  • The proposed BCSM offers a flexible and efficient framework for analyzing multivariate response times, particularly in digitally based assessments.
  • The novel conjugate priors enhance the practical utility of the BCSM for statistical inference and model selection.
  • An empirical example confirmed the BCSM's ability to assess the impact of item presentation formats on student test performance.