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Nonnegative Shared Subspace Learning and Its Application to Social Media Retrieval

Nonnegative Shared Subspace Learning and Its Application to Social Media Retrieval. Sunil Kumar Gupta , Dinh Phung , Brett Adams, Tran The Truyen , Svetha Venkatesh Institute for Multi-sensor Processing & Content Analysis (IMPCA) Curtin University of Technology, Perth, Australia

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Nonnegative Shared Subspace Learning and Its Application to Social Media Retrieval

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  1. NonnegativeShared Subspace Learning andIts Application to Social Media Retrieval Sunil Kumar Gupta, DinhPhung, Brett Adams, Tran The Truyen, SvethaVenkatesh Institute for Multi-sensor Processing & Content Analysis (IMPCA) Curtin University of Technology, Perth, Australia KDD 2010, Washington DC 28th July, 2010

  2. Outline • Introduction • Motivation • Shared Subspace Learning • Social Media Retrieval • Experimental Results • Conclusion

  3. Introduction • Social tags have the potential to improve search,personal organization and have been instrumental in the rising popularity of social sharing sites such as Del.icio.us, Flickr and YouTube. • However, these tags are often very subjective, ambiguous and incomplete [17, 14] due to the lack of constraints during their creation. • The tag quality should be improved for better retrieval performance.

  4. Problem Aim To improve tag-based search performance in social media by transferring knowledge across related auxiliary sources. Motivation • Tags in some tagging systems are cleaner. • Why? Because they are created with controlled vocabulary for different purpose (e.g. object detection) • Can we do “knowledge-transfer” from these cleaner tagging systems to improve search in noisy tagging systems?

  5. Related Works Flickr image and tags LabelMe image and tags hawaii maui hdr tree building person woman tree bench window roof sidewalk road sky cloud Related works • Marlow et al.[17] study user tagging behaviour • Li et al. [14,15] present a method to learn tag relevance • Wang et al. [24] do content based processing and fuse with text-based retrieval results

  6. Text Mining : NMF • NMF aims to factorize a nonnegative data matrix X as • NMF is widely used in text mining applications due to its ability to find part-based and intuitive representation. where and usually,

  7. Nonnegative Shared Subspace Learning (JSNMF) Let us represent the two datasets by X, Y with dimension MxN1 and MxN2 respectively and write the decomposition as : Flickr LabelMe W U V Optimize the cost function

  8. Illustration of NMF and JS-NMF Individual Basis Vectors Common Basis Vector Consider toy datasets X1 (shown in red) and X2 (shown in blue) each having 2 clusters Apply standard NMF to determine 2 basis vectors for each data Treat both data similar by augmenting them together and use NMF with K = 3 Use JSNMF framework with one shared vector

  9. Social Media Retrieval JSNMF based retrieval algorithm Query set (SQ) Project qx on the subspace (qh) Construct query vector qx using vocabulary D and SQ Vocabulary (D) {Retrieved items} Rank the similarities in decreasing order Compute cosine similarity between query vector and the items in the subspace No. of items(N)

  10. Experiments Data collection • We created our dataset by crawling metadata for 50000 images (Flickr), 12000 videos (YouTube ) and used 7000 images (LabelMe). • To download data, we used a variety of concepts • Indoor (‘chair’, ‘computer’, ‘cup’, ‘door’, ‘desk’, ‘microwave’) • Outdoor (‘beach’, ‘boat’, ‘building’, ‘plane’, ‘ship’, ‘sky’, ‘tree’) • Generic (‘book’, ‘car’, ‘pen’, ‘person’, ‘phone’, ‘picture’, ‘window’).

  11. Choice of Shared Subspace Dimensionality (K) • Find the number of the common features (tags in our case) between the two datasets, say Mxy. • Use “the rule of thumb” suggested by [K.V. Mardia et al 1979, Multivariate Analysis] as Figure: Sharing Configuration

  12. Another way to estimate K : supposedly, if subspaces spanned by W, U and V are mutually-orthogonal then However, in our case, W, U and V are only approximately mutually-orthogonal, suggesting that Choice of Shared Subspace Dimensionality (K) Figure: Sharing Configuration

  13. Effect of Shared Subspace Dimensionality (K) No Sharing Full Sharing BASELINES Baseline-I :NMF (No sharing) Baseline-II:JSNMF with full-sharing (Lin et al. [16]) RESULTS SUMMARY

  14. Flickr Retrieval Results P@N, MAP and 11-point interpolated precision-recall results (a) Precision-Scope and MAP results for JSNMF, baseline-I (NMF) and baseline-II (Fully Shared) (b) 11-point interpolated precision recall for JSNMF, baseline-I (NMF) and baseline-II (Fully Shared)

  15. YouTube Retrieval Results P@N, MAP and 11-point interpolated precision-recall results (a) Precision-Scope and MAP results for JSNMF, baseline-I (NMF) and baseline-II (Fully Shared) (b) 11-point interpolated precision recall for JSNMF, baseline-I (NMF) and baseline-II (Fully Shared)

  16. Conclusion • We presented a novel nonnegative shared subspace learning framework. • We demonstrated its application to improve tag-based image and video retrieval in Flickr and YouTube respectively. • We empirically demonstrated that controlled sharing is crucial to avoid any negative knowledge-transfer from auxiliary data sources. • Our JSNMF framework is generic and can be applied widely to carry out flexible knowledge transfer from related data sources.

  17. References [1] http://code.google.com/apis/youtube/overview.html. Accessed in Oct, 2009. [2] http://www.flickr.com/services/api/. Accessed in July, 2009. [3] H.D. Abdulla, M. Polovincak, and V. Snasel. Search Results Clustering using Nonnegative Matrix Factorization (NMF). ASONAM ’09, pages 320–323, July 2009. [4] M.W. Berry and M. Browne. Email Surveillance using Non-negative Matrix Factorization. Computational & Mathematical Organization Theory, 11(3):249–264, 2005. [5] R. Caruana. Multitask learning. Machine Learning, 28(1):41–75,1997. [6] A.P. Dempster, N.M. Laird, D.B. Rubin, et al. Maximum Likelihood from Incomplete Data via the EM Algorithm. Journal of the Royal Statistical Society. Series B (Methodological), 39(1):1–38, 1977. [7] L. Fei-Fei, R. Fergus, and P. Perona. One-shot Learning of Object Categories. PAMI, 28(4):594–611, 2006. [8] S.A. Golder and B.A. Huberman. Usage Patterns of Collaborative Tagging Systems. Journal of Information Science, 32(2):198, 2006. [9] D.R. Hardoon, S. Szedmak, and J. Shawe-Taylor. Canonical Correlation Analysis: An Overview With Application To Learning Methods. Neural Computation, 16(12):2639–2664, 2004. [10] P.O. Hoyer. Non-negative Matrix Factorization with Sparseness Constraints. The Journal of Machine Learning Research, 5:1457– 1469, 2004. [11] M.S. Kankanhalli and Y. Rui. Application Potential of Multimedia Information Retrieval. Proceedings of the IEEE, 96(4):712, 2008. [12] J.R. Kettenring. Canonical Analysis of Several Sets of Variables. Biometrika, 58(3):433–451, 1971. [13] D.D. Lee and H.S. Seung. Algorithms for Non-negative Matrix Factorization. In Advances in Neural Information Processing, 2000. [14] X. Li, C. G. M. Snoek, and M.Worring. Learning Social Tag Relevance by Neighbour Voting. IEEE Transactions on Multimedia, in press, 2009. [15] X. Li, C.G.M. Snoek, and M. Worring. Annotating Images by Harnessing Worldwide User-tagged Photos. ICASSP. Taipei, Taiwan, 2009.

  18. References [16] Y.R. Lin, H. Sundaram, M. De Choudhury, and A. Kelliher. Temporal Patterns in Social Media Streams: Theme Discovery And Evolution Using Joint Analysis Of Content and Context. In ICME 2009, pages 1456–1459, 2009. [17] C. Marlow, M. Naaman, D. Boyd, and M. Davis. Ht06, Tagging Paper, Taxonomy, Flickr, Academic Article, Toread. Proceedings Of The Seventeenth Conference On Hypertext And Hypermedia, pages 31–40, 2006. [18] S.J. Pan and Q. Yang. A Survey on Transfer Learning. Technical Report HKUST-CS08-08, Department of Computer Science and Engineering, HKUST, Hong Kong, China, 2008. [19] R. Raina, A. Battle, H. Lee, B. Packer, and A.Y. Ng. Self-taught Learning: Transfer Learning from Unlabeled Data. Proceedings of the 24th International Conference on Machine Learning, page 766, 2007. [20] B.C. Russell, A. Torralba, K.P. Murphy, andW.T. Freeman. Labelme: A Database and Web-based Tool for Image Annotation. International Journal of Computer Vision, 77(1):157–173, 2008. [21] G. Salton and C. Buckley. Term-weighting Approaches in Automatic Text Retrieval. Information Processing & Management, 24(5):513–523, 1988. [22] F. Shahnaz, M.W. Berry, V.P. Pauca, and R.J. Plemmons. Document Clustering using Nonnegative Matrix Factorization. Information Processing and Management, 42(2):373–386, 2006. [23] B. Sigurbjörnsson and R. Van Zwol. Flickr Tag Recommendation based on Collective Knowledge. Proceeding of ACM International World Wide Web Conference, 2008. [24] C. Wang, F. Jing, L. Zhang, and H.J. Zhang. Scalable Search-based Image Annotation. Multimedia Systems, 14(4):205–220, 2008. [25] X. Wang, C. Pal, and A. McCallum. Generalized Component Analysis for Text with Heterogeneous Attributes. Proceedings of the 13th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, page 803, 2007. [26] L. Wu, L. Yang, N. Yu, and X.S. Hua. Learning to Tag. Proceedings of the 18th International Conference on World Wide Web, pages 361–370, 2009. [27] Z.Wu, C.W. Cheng, and C. Li. Social and Semantics Analysis via Nonnegative Matrix Factorization. Proceedings of the 17th International Conference on World Wide Web, 2008.

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