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Main Authors: Li, Zheng, Wang, Yunhao, Gao, Wei, Ng, Hon Keung Tony
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.02372
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author Li, Zheng
Wang, Yunhao
Gao, Wei
Ng, Hon Keung Tony
author_facet Li, Zheng
Wang, Yunhao
Gao, Wei
Ng, Hon Keung Tony
contents Dimension reduction techniques, such as Sufficient Dimension Reduction (SDR), are indispensable for analyzing high-dimensional datasets. This paper introduces a novel SDR method named Principal Square Response Forward Regression (PSRFR) for estimating the central subspace of the response variable Y, given the vector of predictor variables $\bm{X}$. We provide a computational algorithm for implementing PSRFR and establish its consistency and asymptotic properties. Monte Carlo simulations are conducted to assess the performance, efficiency, and robustness of the proposed method. Notably, PSRFR exhibits commendable performance in scenarios where the variance of each component becomes increasingly dissimilar, particularly when the predictor variables follow an elliptical distribution. Furthermore, we illustrate and validate the effectiveness of PSRFR using a real-world dataset concerning wine quality. Our findings underscore the utility and reliability of the PSRFR method in practical applications of dimension reduction for high-dimensional data analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2409_02372
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Principal Square Response Forward Regression Method for Dimension Reduction
Li, Zheng
Wang, Yunhao
Gao, Wei
Ng, Hon Keung Tony
Methodology
Dimension reduction techniques, such as Sufficient Dimension Reduction (SDR), are indispensable for analyzing high-dimensional datasets. This paper introduces a novel SDR method named Principal Square Response Forward Regression (PSRFR) for estimating the central subspace of the response variable Y, given the vector of predictor variables $\bm{X}$. We provide a computational algorithm for implementing PSRFR and establish its consistency and asymptotic properties. Monte Carlo simulations are conducted to assess the performance, efficiency, and robustness of the proposed method. Notably, PSRFR exhibits commendable performance in scenarios where the variance of each component becomes increasingly dissimilar, particularly when the predictor variables follow an elliptical distribution. Furthermore, we illustrate and validate the effectiveness of PSRFR using a real-world dataset concerning wine quality. Our findings underscore the utility and reliability of the PSRFR method in practical applications of dimension reduction for high-dimensional data analysis.
title A Principal Square Response Forward Regression Method for Dimension Reduction
topic Methodology
url https://arxiv.org/abs/2409.02372