Likelihood inference for correlated binary data without any information about the joint distributions

Tsung Shan Tsou; Wei Cheng Hsiao

doi:10.1080/03610926.2015.1033553

Likelihood inference for correlated binary data without any information about the joint distributions

Tsung Shan Tsou, Wei Cheng Hsiao

Graduate Institute of Statistics

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a universal robust likelihood that is able to accommodate correlated binary data without any information about the underlying joint distributions. This likelihood function is asymptotically valid for the regression parameter for any underlying correlation configurations, including varying under- or over-dispersion situations, which undermines one of the regularity conditions ensuring the validity of crucial large sample theories. This robust likelihood procedure can be easily implemented by using any statistical software that provides naïve and sandwich covariance matrices for regression parameter estimates. Simulations and real data analyses are used to demonstrate the efficacy of this parametric robust method.

Original language	English
Pages (from-to)	2151-2160
Number of pages	10
Journal	Communications in Statistics - Theory and Methods
Volume	46
Issue number	5
DOIs	https://doi.org/10.1080/03610926.2015.1033553
State	Published - 4 Mar 2017

Keywords

Binomial model
Correlated binary data
Logistic regression
Model misspecification
Robust likelihood

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10.1080/03610926.2015.1033553

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abstract = "We propose a universal robust likelihood that is able to accommodate correlated binary data without any information about the underlying joint distributions. This likelihood function is asymptotically valid for the regression parameter for any underlying correlation configurations, including varying under- or over-dispersion situations, which undermines one of the regularity conditions ensuring the validity of crucial large sample theories. This robust likelihood procedure can be easily implemented by using any statistical software that provides na{\"i}ve and sandwich covariance matrices for regression parameter estimates. Simulations and real data analyses are used to demonstrate the efficacy of this parametric robust method.",

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KW - Binomial model

KW - Correlated binary data

KW - Logistic regression

KW - Model misspecification

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Likelihood inference for correlated binary data without any information about the joint distributions

Abstract

Keywords

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