Model Fitness and Predictive Accuracy in Linear Mixed-Effects Models with Latent Clusters

Waheed B. Yahya; Yusuf Bello; Abdulrazaq AbdulRaheem

doi:10.46481/jnsps.2023.1437

Authors

Waheed B. Yahya
Department of Statistics, , University of Ilorin, P.M.B. 1515, Ilorin, Kwara State
Yusuf Bello
[email protected]

Department of Mathematical Sciences, Federal University, Dutsin-Ma
Abdulrazaq AbdulRaheem
Department of Statistics and Mathematical Sciences, Kwara State University, Malete, P.M.B. 1530, Ilorin, Kwara State, Nigeria.

Keywords:

Clustered data, Primal and dual clusters, Linear mixed-effects models, Model fitness, Predictive accuracy

Abstract

In clustered data, observations within a cluster show similarity between themselves because they share common features different from observations in the other clusters. In a given population, different clustering may surface because correlation may occur across more than one dimension. The existing multilevel analysis techniques of the primal linear mixed-effect models are limited to natural clusters which are often not realistic to capture in real-life situations. Therefore, this paper proposes dual linear mixed models (DLMMs) for modeling unobserved latent clusters when such are present in data sets to yield appreciable gains in model fitness and predictive accuracy. The methodology explored the development and analysis of the dual linear mixed models (DLMMs) based on the derived latent clusters from the natural clusters using multivariate cluster analysis. A published data set on political analysis was used to demonstrate the efficiency of the proposed models. The proposed DLMMs have yielded minimum values of the models' assessment criteria (Akaike information criterion, Bayesian information criterion, and root mean squared error), and hence, outperformed the classical PLMMs in terms of model fitness and predictive accuracy.

Dimensions

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doi.org/10.1177/1065912914530514

Model Fitness and Predictive Accuracy in Linear Mixed-Effects Models with Latent Clusters

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