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Improving generative adversarial networks with simple latent distributions

Publication ,  Journal Article
Zhang, S; Huang, K; Qian, Z; Zhang, R; Hussain, A
Published in: Neural Computing and Applications
October 1, 2021

Generative Adversarial Networks (GANs) have drawn great attention recently since they are the powerful models to generate high-quality images. Although GANs have achieved great success, they usually suffer from unstable training and consequently may lead to the poor generations in some cases. Such drawback is argued mainly due to the difficulties in measuring the divergence between the highly complicated the real and fake data distributions, which are normally in the high-dimensional space. To tackle this problem, previous researchers attempt to search a proper divergence capable of measuring the departure of the complex distributions. In contrast, we attempt to alleviate this problem from a different perspective: while retaining the information as much as possible of the original high dimensional distributions, we learn and leverage an additional latent space where simple distributions are defined in a low-dimensional space; as a result, we can readily compute the distance between two simple distributions with an available divergence measurement. Concretely, to retain the data information, the mutual information is maximized between the variables for the high dimensional complex distributions and the low dimensional simple distributions. The departure of the resulting simple distributions are then measured in the original way of GANs. Additionally, for simplifying the optimization further, we optimize directly the lower bound for mutual information. Termed as SimpleGAN, we conduct the proposed approach over the several different baseline models, i.e., conventional GANs, DCGAN, WGAN-GP, WGAN-GP-res, and LSWGAN-GP on the benchmark CIFAR-10 and STL-10 datasets. SimpleGAN shows the obvious superiority on these baseline models. Furthermore, in comparison with the existing methods measuring directly the distribution departure in the high-dimensional space, our method clearly demonstrates its superiority. Finally, a series of experiments show the advantages of the proposed SimpleGAN.

Duke Scholars

Published In

Neural Computing and Applications

DOI

EISSN

1433-3058

ISSN

0941-0643

Publication Date

October 1, 2021

Volume

33

Issue

20

Start / End Page

13193 / 13203

Related Subject Headings

  • Artificial Intelligence & Image Processing
  • 4611 Machine learning
  • 4603 Computer vision and multimedia computation
  • 4602 Artificial intelligence
  • 1702 Cognitive Sciences
  • 0906 Electrical and Electronic Engineering
  • 0801 Artificial Intelligence and Image Processing
 

Citation

APA
Chicago
ICMJE
MLA
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Zhang, S., Huang, K., Qian, Z., Zhang, R., & Hussain, A. (2021). Improving generative adversarial networks with simple latent distributions. Neural Computing and Applications, 33(20), 13193–13203. https://doi.org/10.1007/s00521-021-05946-3
Zhang, S., K. Huang, Z. Qian, R. Zhang, and A. Hussain. “Improving generative adversarial networks with simple latent distributions.” Neural Computing and Applications 33, no. 20 (October 1, 2021): 13193–203. https://doi.org/10.1007/s00521-021-05946-3.
Zhang S, Huang K, Qian Z, Zhang R, Hussain A. Improving generative adversarial networks with simple latent distributions. Neural Computing and Applications. 2021 Oct 1;33(20):13193–203.
Zhang, S., et al. “Improving generative adversarial networks with simple latent distributions.” Neural Computing and Applications, vol. 33, no. 20, Oct. 2021, pp. 13193–203. Scopus, doi:10.1007/s00521-021-05946-3.
Zhang S, Huang K, Qian Z, Zhang R, Hussain A. Improving generative adversarial networks with simple latent distributions. Neural Computing and Applications. 2021 Oct 1;33(20):13193–13203.
Journal cover image

Published In

Neural Computing and Applications

DOI

EISSN

1433-3058

ISSN

0941-0643

Publication Date

October 1, 2021

Volume

33

Issue

20

Start / End Page

13193 / 13203

Related Subject Headings

  • Artificial Intelligence & Image Processing
  • 4611 Machine learning
  • 4603 Computer vision and multimedia computation
  • 4602 Artificial intelligence
  • 1702 Cognitive Sciences
  • 0906 Electrical and Electronic Engineering
  • 0801 Artificial Intelligence and Image Processing