Label prediction based constrained non-negative matrix factorization for semi-supervised multi-view classification

Semi-supervised multi-view classification can improve the performance by leveraging the information from both labeled and unlabeled data. But it is often a challenge to capture the information from the unlabeled multi-view data. By analyzing the relation between labeled and unlabeled data under mult...

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Bibliographic Details
Published in:Neurocomputing (Amsterdam) 2022-11, Vol.512, p.443-455
Main Authors: Liang, Naiyao, Yang, Zuyuan, Li, Zhenni, Xie, Shengli
Format: Article
Language:English
Subjects:
Constrained non-negative matrix factorization
Label prediction
Multi-view classification
Semi-supervised learning
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Summary:Semi-supervised multi-view classification can improve the performance by leveraging the information from both labeled and unlabeled data. But it is often a challenge to capture the information from the unlabeled multi-view data. By analyzing the relation between labeled and unlabeled data under multi-view scenario, we propose a novel model with the ability of leveraging the latent label information from the unlabeled data. In our model, a label prediction (LP) term is proposed to jointly obtain the predicted labels of unlabeled data from multiple views. The LP term is integrated into a constrained non-negative matrix factorization based multi-view framework. In this way, the LP and the multi-view representation learning are integrated into one joint learning problem, where they boost each other. Particularly, the predicted label vector is formulated to be the one-hot vector, such that the labels can be obtained directly. Moreover, we propose a new lemma about the gradient of the â„“2,1 norm in the case of 3-factor matrix decomposition and its corollary about multi-factor matrix decomposition. Based on which, we develop an efficient algorithm and prove its convergence. Experimental results verify that our method can obtain state-of-the-art performance.
ISSN:0925-2312
1872-8286
DOI:10.1016/j.neucom.2022.09.087