Random effects model-based sufficient dimension reduction for independent clustered data

TL;DR

This paper introduces a novel random effects model for sufficient dimension reduction in clustered data, capturing heterogeneity across clusters and improving estimation accuracy over existing methods.

Contribution

It develops a random effects SDR framework on the Grassmann manifold, with a two-stage estimation algorithm and extensions for mixed predictors, demonstrating superior performance.

Findings

The proposed method accurately estimates central subspaces in clustered data.

Simulation studies show improved performance over existing SDR approaches.

Application reveals key socioeconomic drivers with heterogeneity across countries.

Abstract

Sufficient dimension reduction (SDR) is a popular class of regression methods which aim to find a small number of linear combinations of covariates that capture all the information of the responses i.e., a central subspace. The majority of current methods for SDR focus on the setting of independent observations, while the few techniques that have been developed for clustered data assume the linear transformation is identical across clusters. In this article, we introduce random effects SDR, where cluster-specific random effect central subspaces are assumed to follow a distribution on the Grassmann manifold, and the random effects distribution is characterized by a covariance matrix that captures the heterogeneity between clusters in the SDR process itself. We incorporate random effect SDR within a model-based inverse regression framework. Specifically, we propose a random effects principal fitted components model, where a two-stage algorithm is used to estimate the overall fixed effect central subspace, and predict the cluster-specific random effect central subspaces. We demonstrate the consistency of the proposed estimators, while simulation studies demonstrate the superior performance of the proposed approach compared to global and cluster-specific SDR approaches. We also present extensions of the above model to handle mixed predictors, demonstrating how random effects SDR can be achieved in the case of mixed continuous and binary covariates. Applying the proposed methods to study the longitudinal association between the life expectancy of women and socioeconomic variables across 117 countries, we find log income per capita, infant mortality, and income inequality are the main drivers of a two-dimensional fixed effect central subspace, although there is considerable heterogeneity in how the country-specific central subspaces are driven by the predictors.