AI Article Synopsis

  • The paper focuses on improving the estimation of the central space crucial for sufficient dimension reduction (SDR), especially in the presence of collinear predictors.
  • The authors introduce a generalized envelope model, allowing for semiparametric estimation without strong distributional assumptions, enhancing flexibility in statistical analyses.
  • Their new methods, shown to be robust and accurate through simulations, suggest improvements in predictive capabilities, demonstrating practical applications in a heart failure study and potential synergy with machine learning techniques.

Article Abstract

The estimation of the central space is at the core of the sufficient dimension reduction (SDR) literature. However, it is well known that the finite-sample estimation suffers from collinearity among predictors. Cook et al. (2013) proposed the predictor envelope method under linear models that can alleviate the problem by targeting a bigger space - which not only envelopes the central information, but also partitions the predictors by finding an uncorrelated set of material and immaterial predictors. One limitation of the predictor envelope is that it has strong distributional and modeling assumptions and therefore, it cannot be readily used in semiparametric settings where SDR usually nests. In this paper, we generalize the envelope model by defining the enveloped central space and propose a semiparametric method to estimate it. We derive the entire class of regular and asymptotically linear (RAL) estimators as well as the locally and globally semiparametrically efficient estimators for the enveloped central space. Based on the connection between predictor envelope and partial least square (PLS), our methods can also be used to calculate the PLS space beyond linearity. In the simulations, our methods are shown to be both robust and accurate for estimating the enveloped central space under different settings. Moreover, the downstream analysis using state-of-the-art methods such as machine learning (ML) methods has the potential to achieve much better predictions. We further illustrate our methods in a heart failure study.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11499873PMC
http://dx.doi.org/10.1080/01621459.2023.2252134DOI Listing

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