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Bibliographic Details
Main Authors: Yao, Zhigang, Eltzner, Benjamin, Pham, Tung
Format: Preprint
Published: 2016
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Online Access:https://arxiv.org/abs/1604.04318
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author Yao, Zhigang
Eltzner, Benjamin
Pham, Tung
author_facet Yao, Zhigang
Eltzner, Benjamin
Pham, Tung
contents We propose a novel method of finding principal components in multivariate data sets that lie on an embedded nonlinear Riemannian manifold within a higher-dimensional space. Our aim is to extend the geometric interpretation of PCA, while being able to capture non-geodesic modes of variation in the data. We introduce the concept of a principal sub-manifold, a manifold passing through a reference point, and at any point on the manifold extending in the direction of highest variation in the space spanned by the eigenvectors of the local tangent space PCA. Compared to recent work for the case where the sub-manifold is of dimension one Panaretos et al. (2014)$-$essentially a curve lying on the manifold attempting to capture one-dimensional variation$-$the current setting is much more general. The principal sub-manifold is therefore an extension of the principal flow, accommodating to capture higher dimensional variation in the data. We show the principal sub-manifold yields the ball spanned by the usual principal components in Euclidean space. By means of examples, we illustrate how to find, use and interpret a principal sub-manifold and we present an application in shape analysis.
format Preprint
id arxiv_https___arxiv_org_abs_1604_04318
institution arXiv
publishDate 2016
record_format arxiv
spellingShingle Principal Sub-manifolds
Yao, Zhigang
Eltzner, Benjamin
Pham, Tung
Methodology
We propose a novel method of finding principal components in multivariate data sets that lie on an embedded nonlinear Riemannian manifold within a higher-dimensional space. Our aim is to extend the geometric interpretation of PCA, while being able to capture non-geodesic modes of variation in the data. We introduce the concept of a principal sub-manifold, a manifold passing through a reference point, and at any point on the manifold extending in the direction of highest variation in the space spanned by the eigenvectors of the local tangent space PCA. Compared to recent work for the case where the sub-manifold is of dimension one Panaretos et al. (2014)$-$essentially a curve lying on the manifold attempting to capture one-dimensional variation$-$the current setting is much more general. The principal sub-manifold is therefore an extension of the principal flow, accommodating to capture higher dimensional variation in the data. We show the principal sub-manifold yields the ball spanned by the usual principal components in Euclidean space. By means of examples, we illustrate how to find, use and interpret a principal sub-manifold and we present an application in shape analysis.
title Principal Sub-manifolds
topic Methodology
url https://arxiv.org/abs/1604.04318