Estimation in Large Crossed Random-Effect Models by Data Augmentation

Estimation in mixed linear models is, in general, computationally demanding, since applied problems may involve extensive data sets and large numbers of random effects. Existing computer algorithms are slow and/or require large amounts of memory. These problems are compounded in generalized linear m...

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Veröffentlicht in:	Journal of the Royal Statistical Society. Series A, Statistics in society Statistics in society, 1999-01, Vol.162 (3), p.425-436
Hauptverfasser:	Clayton, David, Rasbash, Jon
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Approximation Artificial insemination Computers Datasets Estimation methods Induced substructures Linear models Markovian processes Modeling Modelling Monte Carlo simulation Multilevel models Software Statistical variance
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container_end_page	436
container_issue	3
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container_title	Journal of the Royal Statistical Society. Series A, Statistics in society
container_volume	162
creator	Clayton, David Rasbash, Jon
description	Estimation in mixed linear models is, in general, computationally demanding, since applied problems may involve extensive data sets and large numbers of random effects. Existing computer algorithms are slow and/or require large amounts of memory. These problems are compounded in generalized linear mixed models for categorical data, since even approximate methods involve fitting of a linear mixed model within steps of an iteratively reweighted least squares algorithm. Only in models in which the random effects are hierarchically nested can the computations for fitting these models to large data sets be carried out rapidly. We describe a data augmentation approach to these computational difficulties in which we repeatedly fit an overlapping series of submodels, incorporating the missing terms in each submodel as 'offsets'. The submodels are chosen so that they have a nested random-effect structure, thus allowing maximum exploitation of the computational efficiency which is available in this case. Examples of the use of the algorithm for both metric and discrete responses are discussed, all calculations being carried out using macros within the MLwiN program.
doi_str_mv	10.1111/1467-985X.00146
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subjects	Algorithms Approximation Artificial insemination Computers Datasets Estimation methods Induced substructures Linear models Markovian processes Modeling Modelling Monte Carlo simulation Multilevel models Software Statistical variance
title	Estimation in Large Crossed Random-Effect Models by Data Augmentation
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