Manifold learning: The price of normalization

Yair Goldberg; Alon Zakai; Dan Kushnir; Ya'acov Ritov

Manifold learning: The price of normalization

Yair Goldberg^*, Alon Zakai, Dan Kushnir, Ya'acov Ritov

^*Corresponding author for this work

Department of Statistics

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

63 Scopus citations

Abstract

We analyze the performance of a class of manifold-learning algorithms that find their output by minimizing a quadratic form under some normalization constraints. This class consists of Locally Linear Embedding (LLE), Laplacian Eigenmap, Local Tangent Space Alignment (LTSA), Hessian Eigenmaps (HLLE), and Diffusion maps. We present and prove conditions on the manifold that are necessary for the success of the algorithms. Both the finite sample case and the limit case are analyzed. We show that there are simple manifolds in which the necessary conditions are violated, and hence the algorithms cannot recover the underlying manifolds. Finally, we present numerical results that demonstrate our claims.

Original language	English
Pages (from-to)	1909-1939
Number of pages	31
Journal	Journal of Machine Learning Research
Volume	9
State	Published - Aug 2008

Keywords

Diffusion maps
Dimensionality reduction
Hessian eigenmap
Laplacian eigenmap
Local tangent space alignment
Locally linear embedding
Manifold learning

Cite this

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title = "Manifold learning: The price of normalization",

abstract = "We analyze the performance of a class of manifold-learning algorithms that find their output by minimizing a quadratic form under some normalization constraints. This class consists of Locally Linear Embedding (LLE), Laplacian Eigenmap, Local Tangent Space Alignment (LTSA), Hessian Eigenmaps (HLLE), and Diffusion maps. We present and prove conditions on the manifold that are necessary for the success of the algorithms. Both the finite sample case and the limit case are analyzed. We show that there are simple manifolds in which the necessary conditions are violated, and hence the algorithms cannot recover the underlying manifolds. Finally, we present numerical results that demonstrate our claims.",

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N2 - We analyze the performance of a class of manifold-learning algorithms that find their output by minimizing a quadratic form under some normalization constraints. This class consists of Locally Linear Embedding (LLE), Laplacian Eigenmap, Local Tangent Space Alignment (LTSA), Hessian Eigenmaps (HLLE), and Diffusion maps. We present and prove conditions on the manifold that are necessary for the success of the algorithms. Both the finite sample case and the limit case are analyzed. We show that there are simple manifolds in which the necessary conditions are violated, and hence the algorithms cannot recover the underlying manifolds. Finally, we present numerical results that demonstrate our claims.

AB - We analyze the performance of a class of manifold-learning algorithms that find their output by minimizing a quadratic form under some normalization constraints. This class consists of Locally Linear Embedding (LLE), Laplacian Eigenmap, Local Tangent Space Alignment (LTSA), Hessian Eigenmaps (HLLE), and Diffusion maps. We present and prove conditions on the manifold that are necessary for the success of the algorithms. Both the finite sample case and the limit case are analyzed. We show that there are simple manifolds in which the necessary conditions are violated, and hence the algorithms cannot recover the underlying manifolds. Finally, we present numerical results that demonstrate our claims.

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KW - Dimensionality reduction

KW - Hessian eigenmap

KW - Laplacian eigenmap

KW - Local tangent space alignment

KW - Locally linear embedding

KW - Manifold learning

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JO - Journal of Machine Learning Research

JF - Journal of Machine Learning Research

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Manifold learning: The price of normalization

Abstract

Keywords

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