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Erschienen in:
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2017 | OriginalPaper | Buchkapitel

Non-redundant Spectral Dimensionality Reduction

verfasst von : Yochai Blau, Tomer Michaeli

Erschienen in: Machine Learning and Knowledge Discovery in Databases

Verlag: Springer International Publishing

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Abstract

Spectral dimensionality reduction algorithms are widely used in numerous domains, including for recognition, segmentation, tracking and visualization. However, despite their popularity, these algorithms suffer from a major limitation known as the “repeated eigen-directions” phenomenon. That is, many of the embedding coordinates they produce typically capture the same direction along the data manifold. This leads to redundant and inefficient representations that do not reveal the true intrinsic dimensionality of the data. In this paper, we propose a general method for avoiding redundancy in spectral algorithms. Our approach relies on replacing the orthogonality constraints underlying those methods by unpredictability constraints. Specifically, we require that each embedding coordinate be unpredictable (in the statistical sense) from all previous ones. We prove that these constraints necessarily prevent redundancy, and provide a simple technique to incorporate them into existing methods. As we illustrate on challenging high-dimensional scenarios, our approach produces significantly more informative and compact representations, which improve visualization and classification tasks.

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Vorheriges Kapitel Including Multi-feature Interactions and Redundancy for Feature Ranking in Mixed Datasets
Nächstes Kapitel Rethinking Unsupervised Feature Selection: From Pseudo Labels to Pseudo Must-Links
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Fußnoten
1
Note that LEM and DFM rather use weighted orthogonality constraints, but they can also be brought into the form of (4) (see supplementary material). Also, note that some methods (e.g. LEM, LLE) rather minimize the objective in (4). These problems can be cast as (4) with the kernel \(\check{\varvec{K}} = \lambda _{\max }\varvec{I}-\varvec{K}\) [4, 17].
 
2
Note that this lemma holds true only for maximization problems.
 
3
In ICA, the number of independent components is equal to the dimension of the data. To obtain a low-dimensional embedding, we applied ICA on the low-dimensional embedding produced by PCA [1].
 
Literatur
1.
Bartlett, M.S., Movellan, J.R., Sejnowski, T.J.: Face recognition by independent component analysis. IEEE Trans. Neural Netw. 13(6), 1450–1464 (2002)CrossRef
2.
Belkin, M., Niyogi, P.: Laplacian eigenmaps for dimensionality reduction and data representation. Neural Comput. 15(6), 1373–1396 (2003)CrossRefMATH
3.
Belkin, M., Niyogi, P.: Semi-supervised learning on Riemannian manifolds. Mach. Learn. 56(1–3), 209–239 (2004)CrossRefMATH
4.
Bengio, Y., Paiement, J.F., Vincent, P., Delalleau, O., Le Roux, N., Ouimet, M.: Out-of-sample extensions for LLE, Isomap, MDS, Eigenmaps, and spectral clustering. In: Advances in Neural Information Processing Systems (NIPS) 16, pp. 177–184 (2004)
5.
6.
Chang, C.C., Lin, C.J.: LIBSVM: a library for support vector machines. ACM Trans. Intell. Syst. Technol. (TIST) 2(3), 27 (2011)
7.
Chang, H., Yeung, D.Y., Xiong, Y.: Super-resolution through neighbor embedding. In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, p. I (2004)
8.
9.
Donoho, D.L., Grimes, C.: Hessian eigenmaps: locally linear embedding techniques for high-dimensional data. Proc. Natl. Acad. Sci. 100(10), 5591–5596 (2003)MathSciNetCrossRefMATH
10.
Dsilva, C.J., Talmon, R., Coifman, R.R., Kevrekidis, I.G.: Parsimonious representation of nonlinear dynamical systems through manifold learning: a chemotaxis case study. Appl. Comput. Harmon. Anal. (2015, in press)
11.
Elgammal, A., Lee, C.S.: Inferring 3D body pose from silhouettes using activity manifold learning. In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, pp. II–681 (2004)
12.
Geng, X., Zhan, D.C., Zhou, Z.H.: Supervised nonlinear dimensionality reduction for visualization and classification. IEEE Trans. Syst. Man Cybern. Part B (Cybern.) 35(6), 1098–1107 (2005)CrossRef
13.
Gerber, S., Tasdizen, T., Whitaker, R.: Robust non-linear dimensionality reduction using successive 1-dimensional Laplacian eigenmaps. In: International Conference on Machine Learning (ICML), pp. 281–288 (2007)
14.
Goldberg, Y., Zakai, A., Kushnir, D., Ritov, Y.: Manifold learning: the price of normalization. J. Mach. Learn. Res. 9, 1909–1939 (2008)MathSciNetMATH
15.
Guo, G., Fu, Y., Dyer, C.R., Huang, T.S.: Image-based human age estimation by manifold learning and locally adjusted robust regression. IEEE Trans. Image Process. 17(7), 1178–1188 (2008)MathSciNetCrossRef
16.
Halko, N., Martinsson, P.G., Tropp, J.A.: Finding structure with randomness: probabilistic algorithms for constructing approximate matrix decompositions. SIAM Rev. 53(2), 217–288 (2011)MathSciNetCrossRefMATH
17.
Ham, J., Lee, D.D., Mika, S., Schölkopf, B.: A kernel view of the dimensionality reduction of manifolds. In: International Conference on Machine Learning (ICML), p. 47 (2004)
18.
He, X., Yan, S., Hu, Y., Niyogi, P., Zhang, H.J.: Face recognition using Laplacianfaces. IEEE Trans. Pattern Anal. Mach. Intell. 27(3), 328–340 (2005)CrossRef
19.
Hyvärinen, A.: Fast and robust fixed-point algorithms for independent component analysis. IEEE Trans. Neural Netw. 10(3), 626–634 (1999)CrossRef
20.
Hyvärinen, A., Pajunen, P.: Nonlinear independent component analysis: existence and uniqueness results. Neural Netw. 12(3), 429–439 (1999)CrossRef
21.
22.
Jutten, C., Herault, J.: Blind separation of sources, part I: an adaptive algorithm based on neuromimetic architecture. Sig. Process. 24(1), 1–10 (1991)CrossRefMATH
23.
LeCun, Y., Bottou, L., Bengio, Y., Haffner, P.: Gradient-based learning applied to document recognition. Proc. IEEE 86(11), 2278–2324 (1998)CrossRef
24.
Lee, C.S., Elgammal, A.: Modeling view and posture manifolds for tracking. In: International Conference on Computer Vision (ICCV), pp. 1–8 (2007)
25.
Lim, H., Camps, O.I., Sznaier, M., Morariu, V.I.: Dynamic appearance modeling for human tracking. In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, pp. 751–757 (2006)
26.
Lim, I.S., de Heras Ciechomski, P., Sarni, S., Thalmann, D.: Planar arrangement of high-dimensional biomedical data sets by Isomap coordinates. In: IEEE Symposium on Computer-Based Medical Systems, pp. 50–55 (2003)
27.
Nadaraya, E.A.: On estimating regression. Theory Probab. Appl. 9(1), 141–142 (1964)CrossRefMATH
28.
Pless, R.: Image spaces and video trajectories: using Isomap to explore video sequences. In: International conference on Computer Vision (ICCV), vol. 3, pp. 1433–1440 (2003)
29.
Raytchev, B., Yoda, I., Sakaue, K.: Head pose estimation by nonlinear manifold learning. In: International Conference on Pattern Recognition (ICPR), vol. 4, pp. 462–466 (2004)
30.
Roweis, S.T., Saul, L.K.: Nonlinear dimensionality reduction by locally linear embedding. Science 290(5500), 2323–2326 (2000)CrossRef
31.
Rubinstein, M., Gutierrez, D., Sorkine, O., Shamir, A.: A comparative study of image retargeting. ACM Trans. Graph. (TOG) 29, 160 (2010)CrossRef
32.
Schölkopf, B., Smola, A., Müller, K.-R.: Kernel principal component analysis. In: Gerstner, W., Germond, A., Hasler, M., Nicoud, J.-D. (eds.) ICANN 1997. LNCS, vol. 1327, pp. 583–588. Springer, Heidelberg (1997). https://​doi.​org/​10.​1007/​BFb0020217
33.
Singer, A., Coifman, R.R.: Non-linear independent component analysis with diffusion maps. Appl. Comput. Harmon. Anal. 25(2), 226–239 (2008)MathSciNetCrossRefMATH
34.
Souvenir, R., Zhang, Q., Pless, R.: Image manifold interpolation using free-form deformations. In: IEEE International Conference on Image Processing (ICIP), pp. 1437–1440 (2006)
35.
Tenenbaum, J.B., De Silva, V., Langford, J.C.: A global geometric framework for nonlinear dimensionality reduction. Science 290(5500), 2319–2323 (2000)CrossRef
36.
Van Der Maaten, L., Postma, E., Van den Herik, J.: Dimensionality reduction: a comparative review. J. Mach. Learn. Res. 10, 66–71 (2009)
37.
Vlachos, M., Domeniconi, C., Gunopulos, D., Kollios, G., Koudas, N.: Non-linear dimensionality reduction techniques for classification and visualization. In: International Conference on Knowledge Discovery and Data Mining, pp. 645–651 (2002)
38.
Wang, Q., Xu, G., Ai, H.: Learning object intrinsic structure for robust visual tracking. In: IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, pp. II-227 (2003)
39.
Watson, G.S.: Smooth regression analysis. Sankhyā: Indian J. Stat. Ser. A 26(4), 359–372 (1964)MathSciNetMATH
40.
Zhang, Z., Chow, T.W., Zhao, M.: Trace ratio optimization-based semi-supervised nonlinear dimensionality reduction for marginal manifold visualization. IEEE Trans. Knowl. Data Eng. 25(5), 1148–1161 (2013)CrossRef
41.
Zhang, Z., Zha, H.: Principal manifolds and nonlinear dimensionality reduction via tangent space alignment. J. Shanghai Univ. 8(4), 406–424 (2004)MathSciNetCrossRefMATH
Metadaten
Titel
Non-redundant Spectral Dimensionality Reduction
verfasst von
Yochai Blau
Tomer Michaeli
Copyright-Jahr
2017
Buch
Machine Learning and Knowledge Discovery in Databases

Print ISBN: 978-3-319-71248-2

Electronic ISBN: 978-3-319-71249-9

Copyright-Jahr: 2017

DOI
https://doi.org/10.1007/978-3-319-71249-9_16