Gaussian processes autoencoder for dimensionality reduction

Lists

Download

Preview

GP Autoencoder_V1.3.pdf - Accepted Version (374kB) | Preview

Tools

Jiang, X., Gao, J., Hong, X. ORCID: https://orcid.org/0000-0002-6832-2298 and Cai, Z. (2014) Gaussian processes autoencoder for dimensionality reduction. In: Part II of Proceeding 18th Pacific-Asia Conference, PAKDD 2014, May 13-16, 2014, Tainan, Taiwan.

Abstract/Summary

Learning low dimensional manifold from highly nonlinear data of high dimensionality has become increasingly important for discovering intrinsic representation that can be utilized for data visualization and preprocessing. The autoencoder is a powerful dimensionality reduction technique based on minimizing reconstruction error, and it has regained popularity because it has been efficiently used for greedy pretraining of deep neural networks. Compared to Neural Network (NN), the superiority of Gaussian Process (GP) has been shown in model inference, optimization and performance. GP has been successfully applied in nonlinear Dimensionality Reduction (DR) algorithms, such as Gaussian Process Latent Variable Model (GPLVM). In this paper we propose the Gaussian Processes Autoencoder Model (GPAM) for dimensionality reduction by extending the classic NN based autoencoder to GP based autoencoder. More interestingly, the novel model can also be viewed as back constrained GPLVM (BC-GPLVM) where the back constraint smooth function is represented by a GP. Experiments verify the performance of the newly proposed model.

Item Type	Conference or Workshop Item (Paper)
URI	https://reading-clone.eprints-hosting.org/id/eprint/39730
Item Type	Conference or Workshop Item
Refereed	Yes
Divisions	Science > School of Mathematical, Physical and Computational Sciences > Department of Computer Science
Download/View statistics	View download statistics for this item

Download Statistics

Downloads

Downloads per month over past year

Deposit Details

Date Deposited:	30 Mar 2015 09:33	Date item deposited into CentAUR
Last Modified:	20 May 2024 17:32	Date item last modified

References

1. Rosman, G., Bronstein, M.M., Bronstein, A.M., Kimmel, R.: Nonlinear dimensionality reduction by topologically constrained isometric embedding. International Journal of Computer Vision 89 (2010) 56{68 2. Bishop, C.: Pattern Recognition and Machine Learning. Information Science and Statistics. Springer (2006) 3. Mardia, K.V., Kent, J.T., Bibby, J.M.: Multivariate analysis. Academic Press, London (1979) 4. Tenenbaum, J.B., de Silva, V., Langford, J.C.: A global geometric framework for nonlinear dimensionality reduction. Science 290 (2000) 2319{2323 5. Roweis, S.T., Saul, L.K.: Nonlinear dimensionality reduction by locally linear embedding. SCIENCE 290 (2000) 2323{2326 6. Scholkopf, B., Smola, A., Muller, K.R.: Nonlinear component analysis as a kernel eigenvalue problem. Neural Computation 10(5) (1998) 1299{1319 7. Lawrence, N.: Probabilistic non-linear principal component analysis with gaussian process latent variable models. Journal of Machine Learning Research 6 (2005) 1783{1816 8. Gao, J., Zhang, J., Tien, D.: Relevance units latent variable model and nonlinear dimensionality reduction. IEEE Transactions on Neural Networks 21 (2010) 123{ 135 9. Jiang, X., Gao, J., Shi, D., Wang, T.: Thin plate spline latent variable models for dimensionality reduction. In: International Joint Conference on Neural Networks (IJCNN). (2012) 1{8 10. Tipping, M.E., Bishop, C.M.: Probabilistic principal component analysis. Journal of the Royal Statistical Society, Series B 61 (1999) 611{622 11. Wang, J.M., Fleet, D.J., Hertzmann, A.: Gaussian process dynamical models. In: Advances in Neural Information Processing Systems (NIPS). (2005) 1441{1448 12. Lawrence, N.D., Quinonero-Candela, J.: Local distance preservation in the gplvm through back constraints. In: International Conference on Machine Learning (ICML), ACM Press (2006) 513{520 13. Urtasun, R., Darrell, T.: Discriminative gaussian process latent variable model for classi�cation. In: International Conference on Machine learning (ICML), ACM (2007) 927{934 14. Jiang, X., Gao, J., Wang, T., Zheng, L.: Supervised latent linear gaussian process latent variable model for dimensionality reduction. IEEE Transactions on Systems, Man, and Cybernetics - Part B: Cybernetics 42(6) (2012) 1620{1632 15. Jiang, X., Gao, J., Hong, X., Cai, Z., Wang, T.: Double gaussian process latent variable model for dimensionality reduction. Submitted (2013) 16. Ek, C.H.: Shared Gaussian Process Latent Variables Models. PhD thesis, Oxford Brookes University (2009) 17. Titsias, M.K., Lawrence, N.D.: Bayesian gaussian process latent variable model. In: International Conference on Arti�cial Intelligence and Statistics (AISTATS). (2010) 18. Cottrell, G.W., Munro, P., Zipser, D.: Learning internal representations from grayscale images: An example of extensional programming. In: Conference of the Cognitive Science Society. (1987) 19. Bengio, Y., Lamblin, P., Popovici, D., Larochelle, H.: Greedy layer-wise training of deep networks. In: Advances in Neural Information Processing Systems. (2007) 20. Neal, R.: Bayesian learning for neural networks. Lecture Notes in Statistics 118 (1996) 21. Rasmussen, C.E., Williams, C.K.I.: Gaussian Processes for Machine Learning. The MIT Press (2006) 22. Snoek, J., Adams, R.P., Larochelle, H.: Nonparametric guidance of autoencoder representations using label information. Journal of Machine Learning Research 13 (2012) 2567{2588 23. Palm, R.B.: Prediction as a candidate for learning deep hierarchical models of data. Master's thesis, Technical University of Denmark (2012) 24. Frank, A., Asuncion, A.: UCI machine learning repository (2010)

University Staff: Request a correction | Centaur Editors: Update this record

Search Google Scholar