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Neural Computing and Applications

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21.04.2018 | Original Article

An improved Twin-KSVC with its applications

verfasst von: Qing Ai, Anna Wang, Yang Wang, Haijing Sun

Erschienen in: Neural Computing and Applications | Ausgabe 10/2019

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Abstract

Twin-KSVC (Xu et al. in Cognit Comput 5(4):580–588, 2013) is a novel multi-classifier, which is an extension of K-SVCR (Angulo et al. in Neurocomputing 55(12):57–77, 2003). Compared with K-SVCR, the Twin-KSVC has higher training speed. However, there are some drawbacks in classical Twin-KSVC. (a) Each pair of sub-classifiers in Twin-KSVC only implements empirical risk minimization, which makes generalization performance reduced. (b) Each pair of sub-classifiers in Twin-KSVC needs to calculate large-scale inverse matrices, which is intractable or even impossible in practical applications. (c) For the large-scale datasets, the classical Twin-KSVC doesn’t offer an appropriate training algorithm. (d) For nonlinear case, the classical Twin-KSVC has to construct additional primal problems based on the approximate kernel-generated surface. For the drawbacks of Twin-KSVC, we propose an improved version in this paper, called ITKSVC. First of all, we introduce regularization terms into each pair of sub-classifiers in Twin-KSVC, which makes each pair of sub-classifiers implement structural risk minimization. Further, we theoretically deduce the dual problems of each pair of sub-classifiers, which makes ITKSVC avoid calculating large-scale inverse matrices. In addition, to improve training speed of each pair of sub-classifiers in ITKSVC for the large-scale datasets, successive overrelaxation method is applied. Finally, the dual problems of each pair of sub-classifiers in ITKSVC can directly apply the kernel trick for nonlinear cases. The experimental results on several benchmark datasets indicate that, compared with Twin-KSVC, the proposed ITKSVC has better classification performance for large-scale datasets.

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Angulo C, Parra X, Catal A (2003) K-SVCR. A support vector machine for multi-class classification. Neurocomputing 55(12):57–77CrossRef

Bennett KP (1999) Combining support vector and mathematical programming methods for classification. MIT Press, Cambridge

Chen SG, Wu XJ (2017) A new fuzzy twin support vector machine for pattern classification. Int J Mach Learn Cybern 8(3):1–12

Chen WJ, Shao YH, Li CN, Deng NY (2016) MLTSVM: a novel twin support vector machine to multi-label learning. Pattern Recogn 52:61–74CrossRef

Froz BR, Filho AODC, Silva AC, Paiva ACD, Nunes RA, Gattass M (2017) Lung nodule classification using artificial crawlers, directional texture and support vector machine. Expert Syst Appl 69:176–188CrossRef

Khemchandani R, Chandra S (2007) Twin support vector machines for pattern classification. IEEE Trans Pattern Anal Mach Intell 29(5):905–910CrossRef

Kong X, Liu X, Shi R, Lee KY (2015) Wind speed prediction using reduced support vector machines with feature selection. Neurocomputing 169:449–456CrossRef

Kreel UHG (1999) Pairwise classification and support vector machines. MIT Press, Cambridge

Kumar MA, Gopal M (2008) Application of smoothing technique on twin support vector machines. Pattern Recogn Lett 29(13):1842–1848CrossRef

10.

Kumar MA, Gopal M (2009) Least squares twin support vector machines for pattern classification. Expert Syst Appl 36(4):7535–7543CrossRef

11.

Liu J, Li YF, Zio E (2017) A svm framework for fault detection of the braking system in a high speed train. Mech Syst Signal Process 87:401–409CrossRef

12.

Mangasarian OL, Musicant DR (1999) Successive overrelaxation for support vector machines. IEEE Trans Neural Netw 10(5):1032–1037CrossRef

13.

Mehrkanoon S, Huang X, Suykens JAK (2014) Non-parallel support vector classifiers with different loss functions. Neurocomputing 143(16):294–301CrossRef

14.

Nasiri JA, Charkari NM, Jalili S (2015) Least squares twin multi-class classification support vector machine. Pattern Recogn 48(3):984–992CrossRef

15.

Peng X, Xu D (2012) Twin mahalanobis distance-based support vector machines for pattern recognition. Inf Sci 200(1):22–37MathSciNetCrossRef

16.

Peng X (2010) A \(\nu\)-twin support vector machine (\(\nu\)-tsvm) classifier and its geometric algorithms. Inf Sci 180(20):3863–3875MathSciNetCrossRef

17.

Peng X (2011) TPMSVM: a novel twin parametric-margin support vector machine for pattern recognition. Pattern Recogn 44(10–11):2678–2692CrossRef

18.

Qi Z, Tian Y, Shi Y (2013) Robust twin support vector machine for pattern classification. Pattern Recogn 46(1):305–316CrossRef

19.

Qi Z, Tian Y, Shi Y (2013) Structural twin support vector machine for classification. Knowl-Based Syst 43(2):74–81CrossRef

20.

Rios EG, Hernandez EE, Miyatake MN, Meana HP (2017) Face recognition with occlusion using a wireframe model and support vector machine. IEEE Latin Am Trans 15(10):1960–1966CrossRef

21.

Shao YH, Zhang CH, Wang XB, Deng NY (2011) Improvements on twin support vector machines. IEEE Trans Neural Netw 22(6):962–968CrossRef

22.

Tian Y, Qi Z, Ju X, Shi Y, Liu X (2014) Nonparallel support vector machines for pattern classification. IEEE Trans Cybern 44(7):1067–1079CrossRef

23.

Tian YJ, Ju X, Qi Z, Shi Y (2014) Improved twin support vector machine. Sci China Math 57(2):417–432MathSciNetCrossRef

24.

Vapnik VN (2000) The nature of statistic learning theory. Springer, BerlinCrossRef

25.

Wang Z, Shao YH, Bai L, Deng NY (2015) Twin support vector machine for clustering. IEEE Trans Neural Netw Learn Syst 26(10):2583–2588MathSciNetCrossRef

26.

Xu Y (2016) K-nearest neighbor-based weighted multi-class twin support vector machine. Neurocomputing 205:430–438CrossRef

27.

Xu Y, Guo R, Wang L (2013) A twin multi-class classification support vector machine. Cognit Comput 5(4):580–588CrossRef

28.

Xu Y, Yang Z, Pan X (2017) A novel twin support-vector machine with pinball loss. IEEE Trans Neural Netw Learn Syst 28(2):359–370MathSciNetCrossRef

29.

Xu Y, Yang Z, Zhang Y, Pan X, Wang L (2016) A maximum margin and minimum volume hyper-spheres machine with pinball loss for imbalanced data classification. Knowl-Based Syst 95(C):75–85CrossRef

30.

Ye Q, Zhao C, Gao S, Zheng H (2012) Weighted twin support vector machines with local information and its application. Neural Netw 35(11):31–39CrossRef

31.

Ye Q, Zhao C, Ye N, Chen X (2011) Localized twin svm via convex minimization. Neurocomputing 74(4):580–587CrossRef

32.

Zago L, Hervé PY, Genuer R, Laurent A, Mazoyer B, Tzourio-Mazoyer N, Joliot M (2017) Predicting hemispheric dominance for language production in healthy individuals using support vector machine. Hum Brain Mapp 38(12):5871–5889CrossRef

33.

Zhang H, Chow TW, Wu QM (2016) Organizing books and authors by multilayer som. IEEE Trans Neural Netw Learn Syst 27(12):2537–2550CrossRef

34.

Zhang H, Ho JKL, Wu QMJ, Ye Y (2013) Multidimensional latent semantic analysis using term spatial information. IEEE Trans Cybern 43(6):1625–1640CrossRef

Titel: An improved Twin-KSVC with its applications
verfasst von: Qing Ai
Anna Wang
Yang Wang
Haijing Sun
Publikationsdatum: 21.04.2018
Verlag: Springer London
Erschienen in: Neural Computing and Applications / Ausgabe 10/2019
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-018-3487-0

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