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Cognitive Computation

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06-01-2020

AEKOC+: Kernel Ridge Regression-Based Auto-Encoder for One-Class Classification Using Privileged Information

Authors: Chandan Gautam, Aruna Tiwari, M. Tanveer

Published in: Cognitive Computation | Issue 2/2020

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Abstract

In recent years, non-iterative learning approaches for kernel have received quite an attention by researchers and kernel ridge regression (KRR) approach is one of them. Recently, KRR-based Auto-Encoder is developed for the one-class classification (OCC) task and named as AEKOC. OCC is generally used for outlier or novelty detection. The brain can detect outlier just by learning from only normal samples. Similarly, OCC also uses only normal samples to train the model, and trained model can be used for outlier detection. In this paper, AEKOC is enabled to utilize privileged information, which is generally ignored by AEKOC or any traditional machine learning technique but usually present in human learning. For this purpose, we have combined learning using privileged information (LUPI) framework with AEKOC, and proposed a classifier, which is referred to as AEKOC+. Privileged information is only available during training but not during testing. Therefore, AEKOC is unable to utilize this information for building the model. However, AEKOC+ can efficiently handle the privileged information due to the inclusion of the LUPI framework with AEKOC. Experiments have been conducted on MNIST dataset and on various other datasets from UCI machine learning repository, which demonstrates the superiority of AEKOC+ over AEKOC. Our formulation shows that AEKOC does not utilize the privileged features in learning; however, formulation of AEKOC+ helps it in learning from the privileged features differently from other available features and improved generalization performance of AEKOC. Moreover, AEKOC+ also outperformed two LUPI framework–based one-class classifiers (i.e., OCSVM+ and SSVDD+).

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Some researchers [45, 46] followed the name of kernel extreme learning machine (KELM) [49‐51], and some researchers followed the name of KRR [42, 47] instead of KELM. We do not want to go in the debate of the naming convention. Since there are no differences in the final solution of KELM and KRR, we decided to follow the traditional name KRR instead of KELM. However, we kept both names in this paper to avoid the confusion, i.e., KRR/KELM-based Auto-Encoder for OCC is referred to as AEKOC/AAKELM in this paper.

https://github.com/Chandan-IITI

https://github.com/Chandan-IITI/svmplus_matlab/tree/master/data

Wang S, Chen S, Chen T, Shi X. Learning with privileged information for multi-label classification. Pattern Recogn 2018;81:60–70.CrossRef

Chevalier M, Thome N, Hénaff G, Cord M. Classifying low-resolution images by integrating privileged information in deep CNNs. Pattern Recogn Lett 2018;116:29–35.CrossRef

Lambert J, Sener O, Savarese S. Deep learning under privileged information using heteroscedastic dropout. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition; 2018. p. 8886–8895.

Burnaev E, Smolyakov D. One-class SVM with privileged information and its application to malware detection. IEEE International Conference on Data Mining Workshops, ICDM workshops; 2016. p. 12–15.

Motiian S, Piccirilli M, Adjeroh DA, Doretto G. Information bottleneck learning using privileged information for visual recognition. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition; 2016. p. 1496–1505.

Zhang W. Support vector data description using privileged information. Electron Lett 2015;51(14):1075–1076.CrossRef

Vapnik V, Izmailov R. Learning using privileged information: similarity control and knowledge transfer. J Mach Learn Res 2015;16(2023-2049):2.

Lapin M, Hein M, Schiele B. Learning using privileged information: SVM+ and weighted SVM. Neural Netw 2014;53:95–108.PubMedCrossRef

Zhu W, Zhong P. A new one-class SVM based on hidden information. Knowl-Based Syst 2014;60:35–43.CrossRef

10.

Feyereisl J, Aickelin U. Privileged information for data clustering. Inf Sci 2012;194:4–23.CrossRef

11.

Vapnik V, Vashist A. A new learning paradigm: learning using privileged information. Neural Netw 2009; 22(5-6):544–557.PubMedCrossRef

12.

Xu X, Li W, Xu D. Distance metric learning using privileged information for face verification and person re-identification. IEEE Trans Neural Netw Learn Sys 2015;26(12):3150–3162.CrossRef

13.

Li W, Niu L, Xu D. Exploiting privileged information from web data for image categorization. European Conference on Computer Vision. Springer; 2014. p. 437–452.

14.

Niu L, Li W, Xu D. Exploiting privileged information from web data for action and event recognition. Int J Comput Vis 2016;118(2):130–150.CrossRef

15.

Meng F, Qi Z, Tian Y, Niu L. Pedestrian detection based on the privileged information. Neural Comput & Applic 2018;29(12):1485–1494.CrossRef

16.

Moya MM, Koch MW, Hostetler LD. 1993. One-class classifier networks for target recognition applications. Technical report, Sandia National Labs., Albuquerque, NM (United States).

17.

Khan SS, Madden MG. A survey of recent trends in one class classification. Irish Conference on Artificial Intelligence and Cognitive Science. Springer; 2009. p. 188–197.

18.

Pimentel MA, Clifton DA, Clifton L, Tarassenko L. A review of novelty detection. Signal Process 2014;99:215–249.CrossRef

19.

Xu Y, Liu C. A rough margin-based one class support vector machine. Neural Comput & Applic 2013;22(6): 1077–1084.CrossRef

20.

Hamidzadeh J, Moradi M. Improved one-class classification using filled function. Appl Intell. 2018:1–17.

21.

Gepperth ART, Hecht T, Gogate M. A generative learning approach to sensor fusion and change detection. Cognitive Computation 2016;8(5):806–817.CrossRef

22.

Justo R, Alcaide JM, Torres MI, Walker M. Detection of sarcasm and nastiness: new resources for Spanish language. Cognitive Computation. 2018:1–17.

23.

Anbar M, Abdullah R, Al-Tamimi BN, Hussain A. A machine learning approach to detect router advertisement flooding attacks in next-generation IPv6 networks. Cognitive Computation 2018;10(2):201–214.CrossRef

24.

Tax DMJ. One-class classification; concept-learning in the absence of counter-examples. ASCI dissertation series. 2001:65.

25.

Janakiraman VM, Nielsen D. Anomaly detection in aviation data using extreme learning machines. 2016 International Joint Conference on Neural Networks (IJCNN). IEEE; 2016 . p. 1993–2000.

26.

Yan W. One-class extreme learning machines for gas turbine combustor anomaly detection. 2016 International Joint Conference on Neural Networks (IJCNN). IEEE; 2016. p. 2909–2914.

27.

Gautam C, Tiwari A. Localized multiple kernel support vector data description. 2018 IEEE International Conference on Data Mining Workshops (ICDMW). IEEE; 2018. p. 1514–1521.

28.

Gautam C, Balaji R, Sudharsan K, Tiwari A, Ahuja K. Localized multiple kernel learning for anomaly detection: one-class classification. Knowl-Based Syst 2019;165:241–252.CrossRef

29.

Cai W, Zheng J, Pan W, Lin J, Li L, Chen L, Peng X, Ming Z. Neighborhood-enhanced transfer learning for one-class collaborative filtering. Neurocomputing 2019;341:80–87.CrossRef

30.

Zhou W, Li J, Zhou Y, Memon MH. Bayesian pairwise learning to rank via one-class collaborative filtering. Neurocomputing 2019;367:176–187.CrossRef

31.

Krawczyk B, Triguero I, García S, Woźniak M, Herrera F. Instance reduction for one-class classification. Knowl Inf Syst 2019;59(3):601–628.CrossRef

32.

Manevitz LM, Yousef M. One-class SVMs for document classification. J Mach Learn Res 2001;2(Dec): 139–154.

33.

Yin S, Zhu X, Jing C. Fault detection based on a robust one class support vector machine. Neurocomputing 2014;145:263–268.CrossRef

34.

Mourão-Miranda J, Hardoon DR, Hahn T, Marquand AF, Williams SCR, Shawe-Taylor J, Brammer M. Patient classification as an outlier detection problem: an application of the one- class support vector machine. Neuroimage 2011;58(3):793–804.PubMedCrossRef

35.

Mygdalis V, Iosifidis A, Tefas A, Pitas I. One class classification applied in facial image analysis. 2016 IEEE International Conference on Image Processing (ICIP). IEEE; 2016. p. 1644–1648.

36.

Kozerawski J, Turk M. Clear: Cumulative learning for one-shot one-class image recognition. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition; 2018. p. 3446–3455.

37.

Tax DMJ, Duin RPW. Support vector data description. Mach Learn 2004;54(1):45–66.CrossRef

38.

Schölkopf B, Williamson RC, Smola AJ, Shawe-Taylor J, Platt JC. Support vector method for novelty detection. NIPS; 1999. p. 582–588.

39.

Tax DMJ, Duin RPW. Support vector domain description. Pattern Recogn Lett 1999;20(11):1191–1199.CrossRef

40.

Saunders C, Gammerman A, Vovk V. Ridge regression learning algorithm in dual variables. Proceedings of the Fifteenth International Conference on Machine Learning, ICML ’98. San Francisco: Morgan Kaufmann Publishers Inc; 1998. p. 515–521.

41.

Wornyo DK, Shen X-J, Dong Y, Wang L, Huang S-C. Co-regularized kernel ensemble regression. World Wide Web. 2018:1–18.

42.

Zhang L, Suganthan PN. Benchmarking ensemble classifiers with novel co-trained kernel ridge regression and random vector functional link ensembles [research frontier]. IEEE Comput Intell Mag 2017;12(4):61–72.CrossRef

43.

He J, Ding L, Jiang L, Ma L. Kernel ridge regression classification. 2014 International Joint Conference on Neural Networks (IJCNN). IEEE; 2014. p. 2263–2267.

44.

Wu P-Y, Fang C-C, Chang JM, Kung S-Y. Cost-effective kernel ridge regression implementation for keystroke-based active authentication system. IEEE Transactions on Cybernetics 2017;47(11):3916–3927.PubMedCrossRef

45.

Leng Q, Qi H, Miao J, Zhu W, Su G. One-class classification with extreme learning machine. Math Probl Eng. 2014:1–11.CrossRef

46.

Gautam C, Tiwari A, Leng Q. On the construction of extreme learning machine for online and offline one-class classification—an expanded toolbox. Neurocomputing 2017;261:126–143.CrossRef

47.

Gautam C, Tiwari A, Iosifidis A. Minimum variance-embedded multi-layer kernel ridge regression for one-class classification. 2018 IEEE Symposium Series on Computational Intelligence (SSCI). IEEE; 2018. p. 389–396.

48.

Gautam C, Tiwari A, Suresh S, Ahuja K. Adaptive online learning with regularized kernel for one-class classification. IEEE Transactions on Systems, Man, and Cybernetics: Systems. 2019:1–16.

49.

Huang G-B, Zhu Q-Y, Siew C-K. Extreme learning machine: theory and applications. Neurocomputing 2006;70(1-3):489–501.CrossRef

50.

Huang G-B, Zhou H, Ding X, Zhang R. Extreme learning machine for regression and multiclass classification. IEEE Transactions on Systems, Man, and Cybernetics Part B (Cybernetics) 2011;42(2):513–529.CrossRef

51.

Huang G-B. An insight into extreme learning machines: random neurons, random features and kernels. Cognitive Computation 2014;6(3):376–390.CrossRef

52.

Argyriou A, Micchelli CA, Pontil M. When is there a representer theorem? Vector versus matrix regularizers. J Mach Learn Res 2009;10(Nov):2507–2529.

53.

TU Delft one-class dataset repository. http://homepage.tudelft.nl/n9d04/occ/. Last Accessed by 16 July 2019.

54.

Zhu M. 2004. Recall, precision and average precision. Department of Statistics and Actuarial Science, University of Waterloo, Waterloo, 2:30.

55.

Manning CD, Raghavan P, Schütze H. 2008. Introduction to information retrieval, chapter 13.

56.

Li W, Dai D, Tan M, Xu D, Gool LV. Fast algorithms for linear and kernel SVM+. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition; 2016. p. 2258–2266.

57.

Demšar J. Statistical comparisons of classifiers over multiple data sets. J Mach Learn Res 2006;7(Jan):1–30.

58.

Ieracitano C, Mammone N, Bramanti A, Hussain A, Morabito FC. A convolutional neural network approach for classification of dementia stages based on 2D-spectral representation of EEG recordings. Neurocomputing 2019;323:96–107.CrossRef

59.

Gao F, Huang T, Sun J, Wang J, Hussain A, Yang E. A new algorithm for SAR image target recognition based on an improved deep convolutional neural network. Cognitive Computation. 2018: 1–16.

60.

Ma Y, Peng H, Khan T, Cambria E, Hussain A. Sentic LSTM: a hybrid network for targeted aspect-based sentiment analysis. Cognitive Computation 2018;10(4):639–650.CrossRef

Title: AEKOC+: Kernel Ridge Regression-Based Auto-Encoder for One-Class Classification Using Privileged Information
Authors: Chandan Gautam
Aruna Tiwari
M. Tanveer
Publication date: 06-01-2020
Publisher: Springer US
Published in: Cognitive Computation / Issue 2/2020
Print ISSN: 1866-9956
Electronic ISSN: 1866-9964
DOI: https://doi.org/10.1007/s12559-019-09705-4

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