Journal article
Naidan Tu, Bo Zhang, Lawrence Angrave, Tianjun Sun
Applied Psychological Measurement, 2021
Applied Psychological Measurement, 2021
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APA
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Tu, N., Zhang, B., Angrave, L., & Sun, T. (2021). bmggum: An R Package for Bayesian Estimation of the Multidimensional Generalized Graded Unfolding Model With Covariates. Applied Psychological Measurement.
Chicago/Turabian
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Tu, Naidan, Bo Zhang, Lawrence Angrave, and Tianjun Sun. “Bmggum: An R Package for Bayesian Estimation of the Multidimensional Generalized Graded Unfolding Model With Covariates.” Applied Psychological Measurement (2021).
MLA
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Tu, Naidan, et al. “Bmggum: An R Package for Bayesian Estimation of the Multidimensional Generalized Graded Unfolding Model With Covariates.” Applied Psychological Measurement, 2021.
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@article{naidan2021a,
title = {bmggum: An R Package for Bayesian Estimation of the Multidimensional Generalized Graded Unfolding Model With Covariates},
year = {2021},
journal = {Applied Psychological Measurement},
author = {Tu, Naidan and Zhang, Bo and Angrave, Lawrence and Sun, Tianjun}
}
Abstract
Over the past couple of decades, there has been an increasing interest in adopting ideal point models to represent noncognitive constructs, as they have been demonstrated to better measure typical behaviors than traditional dominance models do. The generalized graded unfolding model (GGUM) has consistently been the most popular ideal point model among researchers and practitioners. However, the GGUM2004 software and the later developed GGUM package in R can only handle unidimensional models despite the fact that many noncognitive constructs are multidimensional in nature. In addition, GGUM2004 and the GGUM package often yield unreasonable estimates of item parameters and standard errors. To address these issues, we developed the new open-source bmggum R package that is capable of estimating both unidimensional and multidimensional GGUM using a fully Bayesian approach, with supporting capabilities of stabilizing parameterization, incorporating person covariates, estimating constrained models, providing fit diagnostics, producing convergence metrics, and effectively handling missing data.