A convex matrix optimization for the additive constant problem in multidimensional scaling with application to locally linear embedding
A convex matrix optimization for the additive constant problem in multidimensional scaling with application to locally linear embedding
The additive constant problem has a long history in multi-dimensional scaling and it has recently been used to resolve the issue of indefiniteness of the geodesic distance matrix in ISOMAP. But it would lead to a large positive constant being added to all eigenvalues of the centered geodesic distance matrix, often causing significant distortion of the original distances. In this paper, we reformulate the problem as a convex optimization of almost negative semidefinite matrix so as to achieve minimal variation of the original distances. We then develop a Newton-CG method and further prove its quadratic convergence. Finally, we include a novel application to the famous LLE (Locally Linear Embedding in nonlinear dimensionality reduction), addressing the issue when the input of LLE has missing values. We justify the use of the developed method to tackle this issue by establishing that the local Gram matrix used in LLE can be obtained through a local Euclidean distance matrix. The effectiveness of our method is demonstrated by numerical experiments.
2564-2590
Qi, Hou-Duo
e9789eb9-c2bc-4b63-9acb-c7e753cc9a85
7 November 2016
Qi, Hou-Duo
e9789eb9-c2bc-4b63-9acb-c7e753cc9a85
Qi, Hou-Duo
(2016)
A convex matrix optimization for the additive constant problem in multidimensional scaling with application to locally linear embedding.
SIAM Journal on Optimization, 26 (4), .
(doi:10.1137/15M1043133).
Abstract
The additive constant problem has a long history in multi-dimensional scaling and it has recently been used to resolve the issue of indefiniteness of the geodesic distance matrix in ISOMAP. But it would lead to a large positive constant being added to all eigenvalues of the centered geodesic distance matrix, often causing significant distortion of the original distances. In this paper, we reformulate the problem as a convex optimization of almost negative semidefinite matrix so as to achieve minimal variation of the original distances. We then develop a Newton-CG method and further prove its quadratic convergence. Finally, we include a novel application to the famous LLE (Locally Linear Embedding in nonlinear dimensionality reduction), addressing the issue when the input of LLE has missing values. We justify the use of the developed method to tackle this issue by establishing that the local Gram matrix used in LLE can be obtained through a local Euclidean distance matrix. The effectiveness of our method is demonstrated by numerical experiments.
Text
LLEMDS_R2.pdf
- Accepted Manuscript
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Published date: 7 November 2016
Organisations:
Operational Research
Identifiers
Local EPrints ID: 391506
URI: http://eprints.soton.ac.uk/id/eprint/391506
ISSN: 1052-6234
PURE UUID: d2a704dd-76b5-46cd-895f-d8afe209b666
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Date deposited: 22 Jun 2016 09:05
Last modified: 15 Mar 2024 03:21
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