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ICML
2005
IEEE
2005
IEEE
Analysis and extension of spectral methods for nonlinear dimensionality reduction
Many unsupervised algorithms for nonlinear dimensionality reduction, such as locally linear embedding (LLE) and Laplacian eigenmaps, are derived from the spectral decompositions of sparse matrices. While these algorithms aim to preserve certain proximity relations on average, their embeddings are not explicitly designed to preserve local features such as distances or angles. In this paper, we show how to construct a low dimensional embedding that maximally preserves angles between nearby data points. The embedding is derived from the bottom eigenvectors of LLE and/or Laplacian eigenmaps by solving an additional (but small) problem in semidefinite programming, whose size is independent of the number of data points. The solution obtained by semidefinite programming also yields an estimate of the data's intrinsic dimensionality. Experimental results on several data sets demonstrate the merits of our approach.
Real-time TrafficICML 2005 | Low Dimensional Embedding | Machine Learning | Nonlinear Dimensionality Reduction | Semidefinite Programming |
Related Content
| Added | 17 Nov 2009 |
| Updated | 17 Nov 2009 |
| Type | Conference |
| Year | 2005 |
| Where | ICML |
| Authors | Fei Sha, Lawrence K. Saul |
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