Global identifiability of latent class models with applications to diagnostic test accuracy studies: A Gröbner basis approach

Rui Duan; Ming Cao; Yang Ning; Mingfu Zhu; Bin Zhang; Aidan McDermott; Haitao Chu; Xiaohua Zhou; Jason H. Moore; Joseph G. Ibrahim; Daniel O. Scharfstein; Yong Chen

doi:10.1111/biom.13133

Global identifiability of latent class models with applications to diagnostic test accuracy studies: A Gröbner basis approach

Rui Duan, Ming Cao, Yang Ning, Mingfu Zhu, Bin Zhang, Aidan McDermott, Haitao Chu, Xiaohua Zhou, Jason H. Moore, Joseph G. Ibrahim, Daniel O. Scharfstein, Yong Chen

Biostatistics

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3 Scopus citations

Abstract

Identifiability of statistical models is a fundamental regularity condition that is required for valid statistical inference. Investigation of model identifiability is mathematically challenging for complex models such as latent class models. Jones et al. used Goodman's technique to investigate the identifiability of latent class models with applications to diagnostic tests in the absence of a gold standard test. The tool they used was based on examining the singularity of the Jacobian or the Fisher information matrix, in order to obtain insights into local identifiability (ie, there exists a neighborhood of a parameter such that no other parameter in the neighborhood leads to the same probability distribution as the parameter). In this paper, we investigate a stronger condition: global identifiability (ie, no two parameters in the parameter space give rise to the same probability distribution), by introducing a powerful mathematical tool from computational algebra: the Gröbner basis. With several existing well-known examples, we argue that the Gröbner basis method is easy to implement and powerful to study global identifiability of latent class models, and is an attractive alternative to the information matrix analysis by Rothenberg and the Jacobian analysis by Goodman and Jones et al.

Original language	English (US)
Pages (from-to)	98-108
Number of pages	11
Journal	Biometrics
Volume	76
Issue number	1
DOIs	https://doi.org/10.1111/biom.13133
State	Published - Mar 1 2020

Bibliographical note

Funding Information:
The authors thank the referees, the associate editor and the editor for their constructive comments that substantially improved the presentation of this work. RD, MC, YN, and MZ are cofirst authors and XZ, JHM, JGI, DOS, and YC are cosenior authors. This work was supported in part by the National Institutes of Health grants 1R01LM012607 (RD and YC), 1R01AI130460 (RD and YC), P50MH113840 (YC), 1R01AI116794 (JHM and YC), R01LM009012 (JHM and YC) and R01LM010098 (JHM). MC was supported by the UTHealth Innovation for Cancer Prevention Research Training Program Pre-doctoral Fellowship (Cancer Prevention and Research Institute of Texas award RP160015). The content is solely the responsibility of the authors and does not necessarily represent the official views of the Cancer Prevention and Research Institute of Texas.

Funding Information:
The authors thank the referees, the associate editor and the editor for their constructive comments that substantially improved the presentation of this work. RD, MC, YN, and MZ are cofirst authors and XZ, JHM, JGI, DOS, and YC are cosenior authors. This work was supported in part by the National Institutes of Health grants 1R01LM012607 (RD and YC), 1R01AI130460 (RD and YC), P50MH113840 (YC), 1R01AI116794 (JHM and YC), R01LM009012 (JHM and YC) and R01LM010098 (JHM). MC was supported by the UTHealth Innovation for Cancer Prevention Research Training Program Pre‐doctoral Fellowship (Cancer Prevention and Research Institute of Texas award RP160015). The content is solely the responsibility of the authors and does not necessarily represent the official views of the Cancer Prevention and Research Institute of Texas.

Publisher Copyright:
© 2019 The International Biometric Society

Keywords

computational algebraic geometry
latent class models
polynomial equations
survey sampling

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title = "Global identifiability of latent class models with applications to diagnostic test accuracy studies: A Gr{\"o}bner basis approach",

abstract = "Identifiability of statistical models is a fundamental regularity condition that is required for valid statistical inference. Investigation of model identifiability is mathematically challenging for complex models such as latent class models. Jones et al. used Goodman's technique to investigate the identifiability of latent class models with applications to diagnostic tests in the absence of a gold standard test. The tool they used was based on examining the singularity of the Jacobian or the Fisher information matrix, in order to obtain insights into local identifiability (ie, there exists a neighborhood of a parameter such that no other parameter in the neighborhood leads to the same probability distribution as the parameter). In this paper, we investigate a stronger condition: global identifiability (ie, no two parameters in the parameter space give rise to the same probability distribution), by introducing a powerful mathematical tool from computational algebra: the Gr{\"o}bner basis. With several existing well-known examples, we argue that the Gr{\"o}bner basis method is easy to implement and powerful to study global identifiability of latent class models, and is an attractive alternative to the information matrix analysis by Rothenberg and the Jacobian analysis by Goodman and Jones et al.",

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author = "Rui Duan and Ming Cao and Yang Ning and Mingfu Zhu and Bin Zhang and Aidan McDermott and Haitao Chu and Xiaohua Zhou and Moore, {Jason H.} and Ibrahim, {Joseph G.} and Scharfstein, {Daniel O.} and Yong Chen",

note = "Funding Information: The authors thank the referees, the associate editor and the editor for their constructive comments that substantially improved the presentation of this work. RD, MC, YN, and MZ are cofirst authors and XZ, JHM, JGI, DOS, and YC are cosenior authors. This work was supported in part by the National Institutes of Health grants 1R01LM012607 (RD and YC), 1R01AI130460 (RD and YC), P50MH113840 (YC), 1R01AI116794 (JHM and YC), R01LM009012 (JHM and YC) and R01LM010098 (JHM). MC was supported by the UTHealth Innovation for Cancer Prevention Research Training Program Pre-doctoral Fellowship (Cancer Prevention and Research Institute of Texas award RP160015). The content is solely the responsibility of the authors and does not necessarily represent the official views of the Cancer Prevention and Research Institute of Texas. Funding Information: The authors thank the referees, the associate editor and the editor for their constructive comments that substantially improved the presentation of this work. RD, MC, YN, and MZ are cofirst authors and XZ, JHM, JGI, DOS, and YC are cosenior authors. This work was supported in part by the National Institutes of Health grants 1R01LM012607 (RD and YC), 1R01AI130460 (RD and YC), P50MH113840 (YC), 1R01AI116794 (JHM and YC), R01LM009012 (JHM and YC) and R01LM010098 (JHM). MC was supported by the UTHealth Innovation for Cancer Prevention Research Training Program Pre‐doctoral Fellowship (Cancer Prevention and Research Institute of Texas award RP160015). The content is solely the responsibility of the authors and does not necessarily represent the official views of the Cancer Prevention and Research Institute of Texas. Publisher Copyright: {\textcopyright} 2019 The International Biometric Society",

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Global identifiability of latent class models with applications to diagnostic test accuracy studies: A Gröbner basis approach

Abstract

Bibliographical note

Keywords

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