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MULFE: Multi-Label Learning via Label-Specific Feature Space Ensemble

Published: 20 July 2021 Publication History

Abstract

In multi-label learning, label correlations commonly exist in the data. Such correlation not only provides useful information, but also imposes significant challenges for multi-label learning. Recently, label-specific feature embedding has been proposed to explore label-specific features from the training data, and uses feature highly customized to the multi-label set for learning. While such feature embedding methods have demonstrated good performance, the creation of the feature embedding space is only based on a single label, without considering label correlations in the data. In this article, we propose to combine multiple label-specific feature spaces, using label correlation, for multi-label learning. The proposed algorithm, multi-label-specific feature space ensemble (MULFE), takes consideration label-specific features, label correlation, and weighted ensemble principle to form a learning framework. By conducting clustering analysis on each label’s negative and positive instances, MULFE first creates features customized to each label. After that, MULFE utilizes the label correlation to optimize the margin distribution of the base classifiers which are induced by the related label-specific feature spaces. By combining multiple label-specific features, label correlation based weighting, and ensemble learning, MULFE achieves maximum margin multi-label classification goal through the underlying optimization framework. Empirical studies on 10 public data sets manifest the effectiveness of MULFE.

References

[1]
Abdelouahid Alalga, Khalid Benabdeslem, and Nora Taleb. 2016. Soft-constrained Laplacian score for semi-supervised multi-label feature selection.Knowledge and Information Systems 47, 1 (2016), 75–98. Retrieved from http://dblp.uni-trier.de/db/journals/kais/kais47.html.
[2]
Shuang An, Qinghua Hu, Witold Pedrycz, Pengfei Zhu, and Eric C. C. Tsang. 2016. Data-distribution-aware fuzzy rough set model and its application to robust classification.IEEE Transactions on Cybernetics 46, 12 (2016), 3073–3085. Retrieved from http://dblp.uni-trier.de/db/journals/tcyb/tcyb46.html.
[3]
Matthew R. Boutell, Jiebo Luo, Xipeng Shen, and C. M. Christopher, M. Brown. 2004. Learning multi-label scene classification. Pattern Recognition 37, 9 (2004), 1757–1771. Retrieved from http://www.sciencedirect.com/science/article/B6V14-4CF14JX-1/2/a17089f241a1d23f218e55d2c8d9f763.
[4]
Tianshui Chen, Muxin Xu, Xiaolu Hui, Hefeng Wu, and Liang Lin. 2019. Learning semantic-specific graph representation for multi-label image recognition. In Proceedings of the 2019 IEEE/CVF International Conference on Computer Vision. 522–531.
[5]
Yixin Chen, Jinbo Bi, and James Z. Wang. 2006. MILES: Multiple-instance learning via embedded instance selection. IEEE Transactions on Pattern Analysis and Machine Intelligence 28, 12 (2006), 1931–1947.
[6]
Zhao-Min Chen, Xiu-Shen Wei, Peng Wang, and Yanwen Guo. 2019. Multi-label image recognition with graph convolutional networks. In Proceedings of the2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR). 5177–5186.
[7]
Chih-Chung, Chang, Chih-Jen, and Lin. 2011. LIBSVM: A library for support vector machines. ACM Transactions on Intelligent Systems and Technology 2, 3 (2011), 2157–6904.
[8]
Moustapha Cisse, Maruan Al-Shedivat, and Samy Bengio. 2016. ADIOS: architectures deep in output space. In International Conference on Machine Learning’16 Proceedings of the 33rd International Conference on International Conference on Machine Learning, Vol. 48. 2770–2779.
[9]
Jianhua Dai, Qinghua Hu, Jinghong Zhang, Hu Hu, and Nenggan Zheng. 2017. Attribute selection for partially labeled categorical data by rough set approach.IEEE Transactions on Cybernetics 47, 9 (2017), 2460–2471. Retrieved from http://dblp.uni-trier.de/db/journals/tcyb/tcyb47.html.
[10]
Grzegorz Drzadzewski and Frank Wm. Tompa. 2016. Partial materialization for online analytical processing over multi-tagged document collections.Knowledge and Information Systems 47, 3 (2016), 697–732. Retrieved from http://dblp.uni-trier.de/db/journals/kais/kais47.html.
[11]
Olive J. Dunn. 1961. Multiple comparisons among means. Journal of the American Statisticial Association 56, 293 (1961), 52–64. Retrieved from http://www.tandfonline.com/doi/full/10.1080/ 01621459.1961.10482090.
[12]
Soumi Dutta, Vibhash Chandra, Kanav Mehra, Asit Kumar Das, Tanmoy Chakraborty, and Saptarshi Ghosh. 2018. Ensemble algorithms for microblog summarization.IEEE Intelligent Systems 33, 3 (2018), 4–14. Retrieved from http://dblp.uni-trier.de/db/journals/expert/expert33.html.
[13]
André Elisseeff and Jason Weston. 2002. A kernel method for multi-labelled classification. In Proceedings of theAdvances in Neural Information Processing Systems, T. G. Dietterich, S. Becker, and Z. Ghahramani (Eds.). 681–687.
[14]
Milton Friedman. 1940. A comparison of alternative tests of significance for the problem of rankings. Annals of Mathematical Statistics 11, 1 (1940), 86–92.
[15]
K. Fukunaga. 1990. Introduction to Statistical Pattern Recognition. Academic Press, New York, NY.
[16]
Johannes Furnkranz, Eyke Hullermeier, Eneldo Loza Mencia, and Klaus Brinker. 2008. Multilabel classification via calibrated label ranking. Machine Learning 73, 2 (2008), 133–153.
[17]
Abdullah Gani, Aisha Siddiqa, Shahaboddin Shamshirband, and Fariza Hanum. 2016. A survey on indexing techniques for big data: taxonomy and performance evaluation. Knowledge and Information Systems 46, 2 (2016), 241–284.
[18]
Tony Van Gestel, Johan A. K. Suykens, Bart Baesens, Stijn Viaene, Jan Vanthienen, Guido Dedene, Bart De Moor, and Joos Vandewalle. 2004. Benchmarking least squares support vector machine classifiers.Machine Learning 54, 1 (2004), 5–32. Retrieved from http://dblp.uni-trier.de/db/journals/ml/ml54.html.
[19]
Richang Hong, Jianxin Pan, Shijie Hao, Meng Wang, Feng Xue, and Xindong Wu. 2014. Image quality assessment based on matching pursuit.Information Sciences 273, 7 (2014), 196–211. Retrieved from http://dblp.uni-trier.de/db/journals/isci/isci273.html.
[20]
Richang Hong, Meng Wang, Yue Gao, Dacheng Tao, Xuelong Li, and Xindong Wu. 2014. Image annotation by multiple-instance learning with discriminative feature mapping and selection.IEEE Transactions on Cybernetics 44, 5 (2014), 669–680. Retrieved from http://dblp.uni-trier.de/db/journals/tcyb/tcyb44.html.
[21]
HOTELLING and H.1936. Relations between two sets of variates. Biometrika 28, 3–4 (1936), 321–377.
[22]
Qinghua Hu, Daren Yu, Zongxia Xie, and Xiaodong Li. 2007. EROS: Ensemble rough subspaces. Pattern Recognition 40, 12 (2007), 3728–3739.
[23]
Qinghua Hu, Pengfei Zhu, Yongbin Yang, and Daren Yu. 2011. Large-margin nearest neighbor classifiers via sample weight learning.Neurocomputing 74, 4 (2011), 656–660. Retrieved from http://dblp.uni-trier.de/db/journals/ijon/ijon74.html.
[24]
Jun Huang, Guorong Li, Qingming Huang, and Xindong Wu. 2016. Learning label-specific features and class-dependent labels for multi-label classification.IEEE Transactions Knowledge and Data Engineering 28, 12 (2016), 3309–3323. Retrieved from http://dblp.uni-trier.de/db/journals/tkde/tkde28.html.
[25]
Jun Huang, Guorong Li, Qingming Huang, and Xindong Wu. 2018. Joint feature selection and classification for multilabel learning.IEEE Transactions on Cybernetics 48, 3 (2018), 876–889. Retrieved from http://dblp.uni-trier.de/db/journals/tcyb/tcyb48.html.
[26]
Jun Huang, Feng Qin, Xiao Zheng, Zekai Cheng, Zhixiang Yuan, Weigang Zhang, and Qingming Huang. 2019. Improving multi-label classification with missing labels by learning label-specific features. Information Sciences 492, 8 (2019), 124–146.
[27]
Seung Jean Kim, K. Koh, M. Lustig, Stephen Boyd, and Dimitry Gorinevsky. 2008. An interior-point method for large-scale l1-regularized least squares. IEEE Journal of Selected Topics in Signal Processing 1, 4 (2008), 606–617.
[28]
Vipin Kumar and Sonajharia Minz. 2016. Multi-view ensemble learning: an optimal feature set partitioning for high-dimensional data classification. Knowledge and Information Systems 49, 1 (2016), 1–59.
[29]
Lei Li, Jianping He, Meng Wang, and Xindong Wu. 2016. Trust agent-based behavior induction in social networks.IEEE Intelligent Systems 31, 1 (2016), 24–30. Retrieved from http://dblp.uni-trier.de/db/journals/expert/expert31.html.
[30]
Yaojin Lin, Qinghua Hu, Jinghua Liu, Jinkun Chen, and Jie Duan. 2016. Multi-label feature selection based on neighborhood mutual information.Applied Soft Computing 38, 1 (2016), 244–256. Retrieved from http://dblp.uni-trier.de/db/journals/asc/asc38.html.
[31]
Yaojin Lin, Qinghua Hu, Jinghua Liu, Jinjin Li, and Xingdong Wu. 2017. Streaming feature selection for multilabel learning based on fuzzy mutual information. IEEE Transactions on Fuzzy Systems 25, 6 (2017), 1491–1507.
[32]
Yaojin Lin, Qinghua Hu, Jia Zhang, and Xindong Wu. 2016. Multi-label feature selection with streaming labels.Information Sciences 372, 11 (2016), 256–275. Retrieved from http://dblp.uni-trier.de/db/journals/isci/isci372.html.
[33]
Huawen Liu, Xuelong Li, and Shichao Zhang. 2017. Learning instance correlation functions for multilabel classification.IEEE Transactions on Cybernetics 47, 2 (2017), 499–510. Retrieved from http://dblp.uni-trier.de/db/journals/tcyb/tcyb47.html.
[34]
Huawen Liu, Shichao Zhang, and Xindong Wu. 2014. MLSLR: Multilabel learning via sparse logistic regression. Information Sciences 281, 10 (2014), 310–320.
[35]
Weiwei Liu, Xiaobo Shen, Haobo Wang, and Ivor W. Tsang. 2020. The emerging trends of multi-label learning. CoRR abs/2011.11197 (2020).
[36]
Jianghong Ma, Bernard Chi Yuen Chiu, and Tommy W. S. Chow. 2020. Multilabel classification with group-based mapping: a framework with local feature selection and local label correlation.IEEE Transactions on Cybernetics.
[37]
Jose M. Moyano, Eva Gibaja, Krzysztof J. Cios, and Sebastian Ventura. 2018. Review of ensembles of multi-label classifiers: Models, experimental study and prospects. Information Fusion 44, (2018), 33–45.
[38]
Yuhua Qian, Feijiang Li, Jiye Liang, Bing Liu, and Chuangyin Dang. 2016. Space structure and clustering of categorical data.IEEE Transactions on Neural Networks and Learning Systems 27, 10 (2016), 2047–2059. Retrieved from http://dblp.uni-trier.de/db/journals/tnn/tnn27.html.
[39]
Yuhua Qian, Hang Xu, Jiye Liang, Bing Liu, and Jieting Wang. 2015. Fusing monotonic decision trees.IEEE Transactions Knowledge and Data Engineering 27, 10 (2015), 2717–2728. Retrieved from http://dblp.uni-trier.de/db/journals/tkde/tkde27.html.
[40]
Jesse Read, Bernhard Pfahringer, Geoffrey Holmes, and Eibe Frank. 2009. Classifier chains for multi-label classification. In Joint European Conference on Machine Learning and Knowledge Discovery in Databases, Wray L. Buntine, Marko Grobelnik, Dunja Mladenic, and John Shawe-Taylor (Eds.). Lecture Notes in Computer Science, Vol. 5782, Springer, 254–269. Retrieved from http://dblp.uni-trier.de/db/conf/pkdd/pkdd2009-2.html.
[41]
Jesse Read, Bernhard Pfahringer, Geoffrey Holmes, and Eibe Frank. 2009. Classifier chains for multi-label classification. In Joint European Conference on Machine Learning and Knowledge Discovery in Databases(), Wray L. Buntine, Marko Grobelnik, Dunja Mladenic, and John Shawe-Taylor (Eds.). Lecture Notes in Computer Science, Vol. 5782. Springer, 254–269. Retrieved from http://dblp.uni-trier.de/db/conf/pkdd/pkdd2009-2.html.
[42]
Saharon Rosset, Ji Zhu, and Trevor Hastie. 2004. Boosting as a regularized path to a maximum margin classifier.Journal of Machine Learning Research 5, (2004), 941–973. Retrieved from http://dblp.uni-trier.de/db/journals/jmlr/jmlr5.html.
[43]
ROBERT E. SCHAPIRE and YORAM SINGER. 2000. BoosTexter: A boosting-based system for text categorization. Machine Learning 39, 2/3 (2000), 135–168.
[44]
Chunhua Shen and Hanxi Li. 2020. Boosting through optimization of margin distributions. IEEE Transactions on Neural Network 21, (2020), 659–666.
[45]
Chunhua Shen and Hanxi Li. 2010. On the dual formulation of boosting algorithms.IEEE Transactions on Pattern Analysis and Machine Intelligence 32, 12 (2010), 2216–2231. Retrieved from http://dblp.uni-trier.de/db/journals/pami/pami32.html.
[46]
K. Trohidis, G. Tsoumakas, G. Kalliris, and I. Vlahavas. 2008. Multi-label classification of music into emotions. In Proceedings of the 9th International Conference on Music Information Retrieval.
[47]
Grigorios Tsoumakas, Ioannis Katakis, and Ioannis Vlahavas. 2009. Mining multi-label data. Data mining and knowledge discovery handbook (2009), 667–685. Retrieved from http://mulan.sourceforge.net/index.html.
[48]
Grigorios Tsoumakas, Ioannis Katakis, and Ioannis Vlahavas. 2010. Random k-labelsets for multi-label classification. IEEE Transactions on Knowledge and Data Engineering 99, 1 (2010). Retrieved from https://doi.org/10.1109/TKDE.2010.164
[49]
Changzhong Wang, Qinghua Hu, Xizhao Wang, Degang Chen, Yuhua Qian, and Zhe Dong. 2018. Feature selection based on neighborhood discrimination index.IEEE Transactions on Neural Networks and Learning Systems 29, 7 (2018), 2986–2999. Retrieved from http://dblp.uni-trier.de/db/journals/tnn/tnn29.html.
[50]
Jiang Wang, Yi Yang, Junhua Mao, Zhiheng Huang, Chang Huang, and Wei Xu. 2016. CNN-RNN: A unified framework for multi-label image classification. In Proceedings of the 2016 IEEE Conference on Computer Vision and Pattern Recognition. 2285–2294.
[51]
Ya Wang, Dongliang He, Fu Li, Xiang Long, Zhichao Zhou, Jinwen Ma, and Shilei Wen. 2020. Multi-label classification with label graph superimposing. In Proceedings of the AAAI Conference on Artificial Intelligence. 12265–12272.
[52]
Tong Wei, Wei-Wei Tu, and Yu-Feng Li. 2019. Learning for tail label data: a label-specific feature approach. In Proceedings of the 28th International Joint Conference on Artificial Intelligence. 3842–3848.
[53]
Herman Wold. 1985. Partial least squares.Encyclopedia of statistical sciences (1985).
[54]
John Wright, Allen Y. Yang, Arvind Ganesh, Shankar S. Sastry, and Yi Ma. 2009. Robust face recognition via sparse representation.IEEE Transactions on Pattern Analysis and Machine Intelligence 31, 2 (2009), 210–227. Retrieved from http://dblp.uni-trier.de/db/journals/pami/pami31.html.
[55]
Jia Wu, Shirui Pan, Xingquan Zhu, Chengqi Zhang, and Xindong Wu. 2018. Multi-instance learning with discriminative bag mapping.IEEE Transactions Knowledge and Data Engineering 30, 6 (2018), 1065–1080. Retrieved from http://dblp.uni-trier.de/db/journals/tkde/tkde30.html.
[56]
Xindong Wu, Xingquan Zhu, Gong-Qing Wu, and Wei Ding. 2014. Data mining with big data. IEEE Transactions on Knowledge and Data Engineering 26, 1 (Jan. 2014), 97–107. Retrieved from https://doi.org/10.1109/TKDE.2013.109
[57]
Xi-Zhu Wu and Zhi-Hua Zhou. 2017. A unified view of multi-label performance measures. In Proceedings of the International Conference on Machine Learning (Proceedings of Machine Learning Research), Doina Precup and Yee Whye Teh (Eds.), Vol. 70. PMLR, 3780–3788. http://dblp.uni-trier.de/db/conf/icml/icml2017.html.
[58]
Chang Xu, Dacheng Tao, and Chao Xu. 2015. Large-margin multi-label causal feature learning. In AAAI, Blai Bonet and Sven Koenig (Eds.). AAAI Press, 1924–1930. http://dblp.uni-trier.de/db/conf/aaai/aaai2015.html.
[59]
Suping Xu, Xibei Yang, Hualong Yu, Dong-Jun Yu, Jingyu Yang, and Eric C. C. Tsang. 2016. Multi-label learning with label-specific feature reduction.Knowledge Based Systems 104 (2016), 52–61. http://dblp.uni-trier.de/db/journals/kbs/kbs104.html.
[60]
Allen Y. Yang, S. Shankar Sastry, Arvind Ganesh, and Yi Ma. 2010. Fast 1-minimization algorithms and an application in robust face recognition: A review. In IEEE International Conference on Image Processing.
[61]
Kui Yu, Xindong Wu, Wei Ding, Yang Mu, and Hao Wang. 2017. Markov blanket feature selection using representative sets.IEEE Transactions on Neural Networks and Learning Systems 28, 11 (2017), 2775–2788. http://dblp.uni-trier.de/db/journals/tnn/tnn28.html.
[62]
Kai Yu, Shipeng Yu, and Volker Tresp. 2005. Multi-label informed latent semantic indexing. In Special Interest Group on Information Retrieval, Ricardo A. Baeza-Yates, Nivio Ziviani, Gary Marchionini, Alistair Moffat, and John Tait (Eds.). ACM, 258–265. http://dblp.uni-trier.de/db/conf/sigir/sigir2005.html.
[63]
Jia Zhang, Candong Li, Donglin Cao, Yaojin Lin, Songzhi Su, Liang Dai, and Shaozi Li. 2018. Multi-label learning with label-specific features by resolving label correlations.Knowledge Based Systems 159 (2018), 148–157. http://dblp.uni-trier.de/db/journals/kbs/kbs159.html.
[64]
Jia Zhang, Candong Li, Zhenqiang Sun, Zhiming Luo, Changen Zhou, and Shaozi Li. 2019. Towards a unified multi-source-based optimization framework for multi-label learning.Applied Soft Computing 76 (2019), 425–435. http://dblp.uni-trier.de/db/journals/asc/asc76.html.
[65]
Minling Zhang, Jose M Pena, and Victor Robles. 2009. Feature selection for multi-label naive Bayes classification. Information Sciences 179, 19 (2009), 3218–3229.
[66]
Minling Zhang and Lei Wu. 2015. Lift : Multi-Label Learning with Label-Specific Features. IEEE Transactions on Pattern Analysis and Machine Intelligence 37, 1 (2015), 107–120.
[67]
M. Zhang and Z. Zhou. 2013. A Review On Multi-Label Learning Algorithms. IEEE Transactions on Knowledge and Data Engineering PP, 99 (2013), 1. https://doi.org/10.1109/TKDE.2013.39
[68]
Min-Ling Zhang and Zhi-Hua Zhou. 2006. Multilabel Neural Networks with Applications to Functional Genomics and Text Categorization.IEEE Transactions Knowledge and Data Engineering 18, 10 (2006), 1338–1351. http://dblp.uni-trier.de/db/journals/tkde/tkde18.html.
[69]
Min-Ling Zhang and Zhi-Hua Zhou. 2007. ML-KNN: A lazy learning approach to multi-label learning.Pattern Recognition 40, 7 (2007), 2038–2048. http://dblp.uni-trier.de/db/journals/pr/pr40.html.
[70]
Qian-Wen Zhang, Yun Zhong, and Min-Ling Zhang. 2018. Feature-Induced Labeling Information Enrichment for Multi-Label Learning. In AAAI, Sheila A. McIlraith and Kilian Q. Weinberger (Eds.). AAAI Press, 4446–4453. http://dblp.uni-trier.de/db/conf/aaai/aaai2018.html.
[71]
Yin Zhang and Zhi-Hua Zhou. 2010. Multilabel dimensionality reduction via dependence maximization.ACM Transactions on Knowledge Discovery from Data 4, 3 (2010), 14:1–14:21. http://dblp.uni-trier.de/db/journals/tkdd/tkdd4.html.
[72]
Jie Zhou, Ganqu Cui, Zhengyan Zhang, Cheng Yang, Zhiyuan Liu, and Maosong Sun. 2018. Graph Neural Networks: A Review of Methods and Applications. Computing Research Repository abs/1812.08434 (2018). arXiv1812.08434. http://arxiv.org/abs/1812.08434.
[73]
Pengfei Zhu and Qinghua Hu. 2013. Adaptive neighborhood granularity selection and combination based on margin distribution optimization.Information Sciences 249 (2013), 1–12. http://dblp.uni-trier.de/db/journals/isci/isci249.html.
[74]
Tianqing Zhu, Gang Li, Wanlei Zhou, Ping Xiong, and Cao Yuan. 2016. Privacy-preserving topic model for tagging recommender systems. Knowledge and Information Systems 46, 1 (2016), 33–58. https://doi.org/10.1007/s10115-015-0832-9

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cover image ACM Transactions on Knowledge Discovery from Data
ACM Transactions on Knowledge Discovery from Data  Volume 16, Issue 1
February 2022
475 pages
ISSN:1556-4681
EISSN:1556-472X
DOI:10.1145/3472794
Issue’s Table of Contents
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Publication History

Published: 20 July 2021
Accepted: 01 February 2021
Revised: 01 January 2021
Received: 01 May 2020
Published in TKDD Volume 16, Issue 1

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Author Tags

  1. Multi-label learning
  2. label correlation
  3. label-specific features
  4. ensemble

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  • Refereed

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  • National Key Research and Development Program of China
  • National Natural Science Foundation of China

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