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Adversarial Multiview Clustering Networks With Adaptive Fusion

Qianqian Wang, Zhiqiang Tao, Wei Xia, Quanxue Gao, Xiaochun Cao, Licheng Jiao

2022IEEE Transactions on Neural Networks and Learning Systems76 citationsDOI

Abstract

The existing deep multiview clustering (MVC) methods are mainly based on autoencoder networks, which seek common latent variables to reconstruct the original input of each view individually. However, due to the view-specific reconstruction loss, it is challenging to extract consistent latent representations over multiple views for clustering. To address this challenge, we propose adversarial MVC (AMvC) networks in this article. The proposed AMvC generates each view’s samples conditioning on the fused latent representations among different views to encourage a more consistent clustering structure. Specifically, multiview encoders are used to extract latent descriptions from all the views, and the corresponding generators are used to generate the reconstructed samples. The discriminative networks and the mean squared loss are jointly utilized for training the multiview encoders and generators to balance the distinctness and consistency of each view’s latent representation. Moreover, an adaptive fusion layer is developed to obtain a shared latent representation, on which a clustering loss and the <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">${\ell _ {1,2}}$ </tex-math></inline-formula> -norm constraint are further imposed to improve clustering performance and distinguish the latent space. Experimental results on video, image, and text datasets demonstrate that the effectiveness of our AMvC is over several state-of-the-art deep MVC methods.

Topics & Concepts

Cluster analysisArtificial intelligenceAutoencoderComputer scienceDiscriminative modelPattern recognition (psychology)Latent variableConsistency (knowledge bases)Adversarial systemInferenceDeep belief networkConstraint (computer-aided design)EncoderSpectral clusteringDeep learningEncoding (memory)Machine learningFeature learningArtificial neural networkUnsupervised learningData miningSimilarity (geometry)Probabilistic latent semantic analysisFusionSensor fusionRepresentation (politics)Data modelingDomain Adaptation and Few-Shot LearningHuman Pose and Action RecognitionFace recognition and analysis
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