Unsupervised domain adaptation based on adaptive local manifold learning

Transfer learning is known to an effective method dealing with domain shift. When the same task is shared in different domains, it is usually called domain adaptation. The problem of distribution difference is inevitable in domain adaption works. The subspace method can transform the data into a new...

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Veröffentlicht in:	Computers & electrical engineering 2022-05, Vol.100, p.107941, Article 107941
Hauptverfasser:	Shi, Kaiming, Liu, Zhonghua, Lu, Wenpeng, Ou, Weihua, Yang, Chunlei
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation Common subspace Domain shift Domains Feature representation Image classification Machine learning Manifold learning Manifolds (mathematics) Object recognition Regularization Representations Subspace methods Subspaces
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creator	Shi, Kaiming Liu, Zhonghua Lu, Wenpeng Ou, Weihua Yang, Chunlei
description	Transfer learning is known to an effective method dealing with domain shift. When the same task is shared in different domains, it is usually called domain adaptation. The problem of distribution difference is inevitable in domain adaption works. The subspace method can transform the data into a new feature representation, which is helpful to reduce the distribution differences. At present, many researchers have made extensive exploration on subspace learning in domain adaptation works. The weakness of many existed domain adaptation methods based on subspace learning either ignores the local manifold information or has the problem of parameter selection in local manifold regularization term which may limit the effectiveness of cross - domain image classification. Therefore, a novel transfer learning method termed unsupervised domain adaptation based on adaptive local manifold learning (UDA-ALML) is proposed in this paper, which is mainly utilized to cross-domain image classification. For the sake of preserving the structure information of original data, the proposed method combines sparse representation, manifold learning and low rank representation to learn the transformation matrix. To be specific, the weight matrix in traditional local manifold regularization term is replaced by the reconstruction coefficient matrix. Large quantities of experiments show that it has a remarkable performance in cross-domain image recognition.
doi_str_mv	10.1016/j.compeleceng.2022.107941
format	Article
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subjects	Adaptation Common subspace Domain shift Domains Feature representation Image classification Machine learning Manifold learning Manifolds (mathematics) Object recognition Regularization Representations Subspace methods Subspaces
title	Unsupervised domain adaptation based on adaptive local manifold learning
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