Joint Domain Adaptation Based on Adversarial Dynamic Parameter Learning

Domain adaptation aims to improve the performance of the classifier in the target domain by reducing the difference between the two domains. Domain shifts usually exist in both marginal distribution and conditional distribution, and their relative importance varies with datasets. Moreover, there is...

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Bibliographic Details
Published inIEEE transactions on emerging topics in computational intelligence Vol. 5; no. 4; pp. 714 - 723
Main Authors Yuan, Yumeng, Li, Yuhua, Zhu, Zhenlong, Li, Ruixuan, Gu, Xiwu
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.08.2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Adaptation
Adversarial learning
Algorithms
Alignment
Datasets
Discriminators
Domain adaptation
Domains
dynamic distribution alignment
Feature extraction
Generative adversarial networks
Image classification
joint distribution alignment
Machine learning
Parameters
Performance enhancement
Supervised learning
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Summary:Domain adaptation aims to improve the performance of the classifier in the target domain by reducing the difference between the two domains. Domain shifts usually exist in both marginal distribution and conditional distribution, and their relative importance varies with datasets. Moreover, there is an influence between marginal distribution distance and conditional distribution distance. However, joint domain adaptation approaches rarely consider those. Existing dynamic distribution alignment methods require a feature discriminator, and they need to train a subdomain discriminator for each class. Besides, they don't think about the interaction between the two distribution distances. In this article, we propose a dynamic joint domain adaptation approach, namely Joint Domain Adaptation Based on Adversarial Dynamic Parameter Learning (ADPL), to deal with the above problems. Both marginal distribution alignment and conditional distribution alignment can be implemented by adversarial learning. The dynamic algorithm can keep a balance between marginal and conditional distribution alignment with only two domain discriminators. In addition, the dynamic algorithm takes the influence between the two distribution distances into consideration. Compared with several advanced domain adaptation methods on both text and image datasets, all classification experiments and extensive comparison experiments demonstrate that ADPL has higher learning performance of classification and less running time. This reveals that ADPL outperforms the state-of-the-art domain adaptation approaches.
ISSN:2471-285X
2471-285X
DOI:10.1109/TETCI.2021.3055873