Statistical regression analysis of functional and shape data

Mengmeng Guo; Jingyong Su; Li Sun; Guofeng Cao

doi:10.1080/02664763.2019.1669541

Statistical regression analysis of functional and shape data

Mengmeng Guo^*
, Jingyong Su
, Li Sun
, Guofeng Cao

^*Corresponding author for this work

Texas Tech University
Harbin Institute of Technology

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

We develop a multivariate regression model when responses or predictors are on nonlinear manifolds, rather than on Euclidean spaces. The nonlinear constraint makes the problem challenging and needs to be studied carefully. By performing principal component analysis (PCA) on tangent space of manifold, we use principal directions instead in the model. Then, the ordinary regression tools can be utilized. We apply the framework to both shape data (ozone hole contours) and functional data (spectrums of absorbance of meat in Tecator dataset). Specifically, we adopt the square-root velocity function representation and parametrization-invariant metric. Experimental results have shown that we can not only perform powerful regression analysis on the non-Euclidean data but also achieve high prediction accuracy by the constructed model.

Original language	English
Pages (from-to)	28-44
Number of pages	17
Journal	Journal of Applied Statistics
Volume	47
Issue number	1
DOIs	https://doi.org/10.1080/02664763.2019.1669541
State	Published - 2 Jan 2020
Externally published	Yes

Keywords

PCA
Riemannian manifolds
Shape analysis
functional regression
square-root velocity function

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10.1080/02664763.2019.1669541

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title = "Statistical regression analysis of functional and shape data",

abstract = "We develop a multivariate regression model when responses or predictors are on nonlinear manifolds, rather than on Euclidean spaces. The nonlinear constraint makes the problem challenging and needs to be studied carefully. By performing principal component analysis (PCA) on tangent space of manifold, we use principal directions instead in the model. Then, the ordinary regression tools can be utilized. We apply the framework to both shape data (ozone hole contours) and functional data (spectrums of absorbance of meat in Tecator dataset). Specifically, we adopt the square-root velocity function representation and parametrization-invariant metric. Experimental results have shown that we can not only perform powerful regression analysis on the non-Euclidean data but also achieve high prediction accuracy by the constructed model.",

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T1 - Statistical regression analysis of functional and shape data

AU - Guo, Mengmeng

AU - Su, Jingyong

AU - Sun, Li

AU - Cao, Guofeng

PY - 2020/1/2

Y1 - 2020/1/2

N2 - We develop a multivariate regression model when responses or predictors are on nonlinear manifolds, rather than on Euclidean spaces. The nonlinear constraint makes the problem challenging and needs to be studied carefully. By performing principal component analysis (PCA) on tangent space of manifold, we use principal directions instead in the model. Then, the ordinary regression tools can be utilized. We apply the framework to both shape data (ozone hole contours) and functional data (spectrums of absorbance of meat in Tecator dataset). Specifically, we adopt the square-root velocity function representation and parametrization-invariant metric. Experimental results have shown that we can not only perform powerful regression analysis on the non-Euclidean data but also achieve high prediction accuracy by the constructed model.

AB - We develop a multivariate regression model when responses or predictors are on nonlinear manifolds, rather than on Euclidean spaces. The nonlinear constraint makes the problem challenging and needs to be studied carefully. By performing principal component analysis (PCA) on tangent space of manifold, we use principal directions instead in the model. Then, the ordinary regression tools can be utilized. We apply the framework to both shape data (ozone hole contours) and functional data (spectrums of absorbance of meat in Tecator dataset). Specifically, we adopt the square-root velocity function representation and parametrization-invariant metric. Experimental results have shown that we can not only perform powerful regression analysis on the non-Euclidean data but also achieve high prediction accuracy by the constructed model.

KW - PCA

KW - Riemannian manifolds

KW - Shape analysis

KW - functional regression

KW - square-root velocity function

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DO - 10.1080/02664763.2019.1669541

M3 - 文章

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VL - 47

SP - 28

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JO - Journal of Applied Statistics

JF - Journal of Applied Statistics

IS - 1

ER -

Statistical regression analysis of functional and shape data

Abstract

Keywords

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