Generative Adversarial Networks: An Overview
About
Generative adversarial networks (GANs) provide a way to learn deep representations without extensively annotated training data. They achieve this through deriving backpropagation signals through a competitive process involving a pair of networks. The representations that can be learned by GANs may be used in a variety of applications, including image synthesis, semantic image editing, style transfer, image super-resolution and classification. The aim of this review paper is to provide an overview of GANs for the signal processing community, drawing on familiar analogies and concepts where possible. In addition to identifying different methods for training and constructing GANs, we also point to remaining challenges in their theory and application.
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Density modeling | Nutrient intake data | CvM0.033 | 12 | |
| Mars Lander Trajectory Generation | RL-25 | Cumulative Control Cost3.35 | 6 | |
| Goodness-of-fit to dependence in the extremes | French Britanny Rainfall J-NSD (test) | IRAE0.03 | 5 | |
| Goodness-of-fit to dependence in the extremes | French Britanny Rainfall G-NSD (test) | IRAE0.07 | 5 | |
| Goodness-of-fit to dependence in the extremes | French Britanny Rainfall (F-NSD) (test) | IRAE0.1 | 5 | |
| Goodness-of-fit to dependence in the extremes | French Britanny Rainfall C-NSD (test) | IRAE0.52 | 5 | |
| High-dimensional density modeling | Clayton-NSD (C-NSD) copula 100-dimensional | CvM Statistic16 | 4 | |
| Mars Lander Trajectory Generation | RL-Hybrid-25 | Cumulative Control Cost5.37 | 3 | |
| Mars Lander Trajectory Generation | S-VAE-1000 | Cumulative Control Cost3.81 | 3 | |
| Mars Lander Trajectory Generation | MI-VAE-25 | Cumulative Control Cost3.69 | 3 |