Conditional Image Synthesis with Auxiliary Classifier GANs: Difference between revisions

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[[#References|Odena et al. (2017)]] argue that the class conditional generator allows $G$ to learn a representation of $Z$ independent of $C$ in section 3, and give evidence of the claim later in section 4.5 by showing that images generated with a fixed latent vector $z$ but different class labels $c$ have similar global structure (e.g. orientation of the subject) but the subjects (bird species) vary according to the label. Interestingly, the background (especially in the top row) also varies with the class label. This can possibly be attributed to the bird species coming from different areas, hence a seagull might be expected to have an ocean background. Clearly here the model benefits from the fact that the authors grouped similar classes together. A more interesting analysis might show the same comparison between different classes, such as birds and forklifts, to see how global structure is encoded across them.
[[#References|Odena et al. (2017)]] argue that the class conditional generator allows $G$ to learn a representation of $Z$ independent of $C$ in section 3, and give evidence of the claim later in section 4.5 by showing that images generated with a fixed latent vector $z$ but different class labels $c$ have similar global structure (e.g. orientation of the subject) but the subjects (bird species) vary according to the label. Interestingly, the background (especially in the top row) also varies with the class label. This can possibly be attributed to the bird species coming from different areas, hence a seagull might be expected to have an ocean background. Clearly here the model benefits from the fact that the authors grouped similar classes together. A more interesting analysis might show the same comparison between different classes, such as birds and forklifts, to see how global structure is encoded across them.


=== Metrics ===
=== GAN Quality Metrics ===


A much larger part of the authors' contributions in this paper is in the area of measuring the quality of a GAN's output. As they say, evaluating a generative model's quality is difficult due to a large number of probabilistic measures (such as average log-likelihood, Parzen window estimates, and visual fidelity [[#References| (Theis et al., 2015)]]).


=== Experiments ===
=== Experiments ===

Revision as of 18:05, 18 November 2017

Abstract: "In this paper we introduce new methods for the improved training of generative adversarial networks (GANs) for image synthesis. We construct a variant of GANs employing label conditioning that results in 128×128 resolution image samples exhibiting global coherence. We expand on previous work for image quality assessment to provide two new analyses for assessing the discriminability and diversity of samples from class-conditional image synthesis models. These analyses demonstrate that high resolution samples provide class information not present in low resolution samples. Across 1000 ImageNet classes, 128×128 samples are more than twice as discriminable as artificially resized 32×32 samples. In addition, 84.7% of the classes have samples exhibiting diversity comparable to real ImageNet data." (Odena et al., 2016)

Introduction

Motivation

The authors introduce a GAN architecture for generating high resolution images from the ImageNet dataset. They show that this architecture makes it possible to split the generation process into many sub-models. They further suggest that GANs have trouble generating globally coherent images, and that this architecture is responsible for the coherence of their samples. They experimentally demonstrate that generating higher resolution images allow the model to encode more class-specific information, making them more visually discriminable than lower resolution images even after they have been resized to the same resolution.

The second half of the paper introduces metrics for assessing visual discriminability and diversity of synthesized images. The discussion of image diversity in particular is important due to the tendency for GANs to 'collapse' to only produce one image that best fools the discriminator (Goodfellow et al., 2014).

Previous Work

Of all image synthesis methods (e.g. variational autoencoders, autoregressive models, invertible density estimators), GANs have become one of the most popular and successful due to their flexibility and the ease with which they can be sampled from. A standard GAN framework pits a generative model $G$ against a discriminative adversary $D$. The goal of $G$ is to learn a mapping from a latent space $Z$ to a real space $X$ to produce examples (generally images) indistinguishable from training data. The goal of the $D$ is to iteratively learn to predict when a given input image is from the training set or a synthesized image from $G$. Jointly the models are trained to solve the game-theoretical minimax problem, as defined by Goodfellow et al. (2014): $$\underset{G}{\text{min }}\underset{D}{\text{max }}V(G,D)=\mathbb{E}_{X\sim p_{data}(x)}[log(D(X))]+\mathbb{E}_{Z\sim p_{Z}(z)}[log(1-D(G(Z)))]$$

While this initial framework has clearly demonstrated great potential, other authors have proposed changes to the method to improve it. Many such papers propose changes to the training process (Salimans et al., 2016)(Karras et al., 2017), which is notoriously difficult for some problems. Others propose changes to the model itself. Mirza & Osindero (2014) augment the model by supplying the class of observations to both the generator and discriminator to produce class-conditional samples. According to van den Oord et al. (2016), conditioning image generation on classes can greatly improve their quality. Other authors have explored using even richer side information in the generation process with good results (Reed et al., 2016).

Another model modification relevant to this paper is to force the discriminator network to reconstruct side information by adding an auxiliary network to classify generated (and real) images. The authors make the claim that forcing a model to perform additional tasks is known to improve performance on the original task (Szegedy et al., 2014)(Sutskever et al., 2014)(Ramsundar et al., 2016). They further suggest that using pre-trained image classifiers (rather than classifiers trained on both real and generated images) could improve results over and above what is shown in this paper.

Contributions

Model

The authors propose an auxiliary classifier GAN (AC-GAN) which is a slight variation on previous architectures. Like Mirza & Osindero (2014), the generator takes the image class to be generated as input in addition to the latent encoding $Z$. Like Odena (2016) and Salimans et al. (2016), the discriminator is trained to predict not only whether an observation is real or fake, but to classify each observation as well. The marginal contribution of this paper is to combine these in one model.

Formally, let $C\sim p_c$ represent the target class label of each generated observation and $Z$ represent the usual noise vector from the latent space. Then the generator function takes both as argument to produce image samples: $X_{fake}=G(c,z)$.The discriminator gives a probability distribution over the source $S$ (real or fake) of the image as well as the class label $C$ being generated. $$D(X)=<P(S|X),P(C|X)>$$

The objective function for the model thus has two parts, one corresponding to the source $L_S$ and the other to the class $L_C$. $D$ is trained to maximize $L_S + L_C$, while $G$ is trained to maximize $L_C-L_S$. Using the notation of Goodfellow et al. (2014), these are: $$L_S=\mathbb{E}_{X\sim p_{data}(x)}[log(P(S=real|X))]+\mathbb{E}_{C,Z\sim p_{C,Z}(c,z)}[log(P(S=fake|G(C,Z)))]$$ $$L_C=\mathbb{E}_{X\sim p_{data}(x)}[log(P(C|X))]+\mathbb{E}_{C,Z\sim p_{C,Z}(c,z)}[log(P(C|G(C,Z)))]$$

Because G accepts both $C$ and $Z$ as arguments, it is able to learn a mapping $Z\rightarrow X$ that is independent of $C$. The authors argure that all class-specific information should be represented by $C$, allowing $Z$ to represent other factors such as pose, background, etc.

Lastly the authors split the generation process into many class-specific submodels. They point out that the structure of their model permits this split, though it should technically be possible for even the standard GAN framework by dividing the training data into groups according to their known class labels.

The changes above result in a model capable of generating (some) image samples with both high resolution and global coherence.

Measurement Methods

The authors propose two measurement methods to assess the discriminability and diversity of the generated images.

Experimental Results on GAN Properties

Results

Critique

Model

Not very different from other GANs. Some unsupported claims about stabilizing training etc. No balancing hyperparameter for classification and discrimination. Never tested/showed whether their architecture is better than others.

(Odena et al., 2017) Figure 9 (Bottom): Each column is a different class. Each row is generated by a different latent encoding $z$.
(Odena et al., 2017) Figure 9 (Bottom): Each column is a different class. Each row is generated by a different latent encoding $z$.

Odena et al. (2017) argue that the class conditional generator allows $G$ to learn a representation of $Z$ independent of $C$ in section 3, and give evidence of the claim later in section 4.5 by showing that images generated with a fixed latent vector $z$ but different class labels $c$ have similar global structure (e.g. orientation of the subject) but the subjects (bird species) vary according to the label. Interestingly, the background (especially in the top row) also varies with the class label. This can possibly be attributed to the bird species coming from different areas, hence a seagull might be expected to have an ocean background. Clearly here the model benefits from the fact that the authors grouped similar classes together. A more interesting analysis might show the same comparison between different classes, such as birds and forklifts, to see how global structure is encoded across them.

GAN Quality Metrics

A much larger part of the authors' contributions in this paper is in the area of measuring the quality of a GAN's output. As they say, evaluating a generative model's quality is difficult due to a large number of probabilistic measures (such as average log-likelihood, Parzen window estimates, and visual fidelity (Theis et al., 2015)).

Experiments

Discussion of overfitting says b/c nearest neighbours under L1 measure in pixel space are not similar looking it doesn't overfit.

Conclusion

References

  1. Odena, A., Olah, C., & Shlens, J. (2016). Conditional image synthesis with auxiliary classifier gans. arXiv preprint arXiv:1610.09585.
  2. Goodfellow, I., Pouget-Abadie, J., Mirza, M., Xu, B., Warde-Farley, D., Ozair, S., ... & Bengio, Y. (2014). Generative adversarial nets. In Advances in neural information processing systems (pp. 2672-2680).
  3. Salimans, T., Goodfellow, I., Zaremba, W., Cheung, V., Radford, A., & Chen, X. (2016). Improved techniques for training gans. In Advances in Neural Information Processing Systems (pp. 2234-2242).
  4. Karras, T., Aila, T., Laine, S., & Lehtinen, J. (2017). Progressive Growing of GANs for Improved Quality, Stability, and Variation. arXiv preprint arXiv:1710.10196.
  5. Mirza, M., & Osindero, S. (2014). Conditional generative adversarial nets. arXiv preprint arXiv:1411.1784.
  6. van den Oord, A., Kalchbrenner, N., Espeholt, L., Vinyals, O., & Graves, A. (2016). Conditional image generation with pixelcnn decoders. In Advances in Neural Information Processing Systems (pp. 4790-4798).
  7. Reed, S. E., Akata, Z., Mohan, S., Tenka, S., Schiele, B., & Lee, H. (2016). Learning what and where to draw. In Advances in Neural Information Processing Systems (pp. 217-225).
  8. Szegedy, C., Liu, W., Jia, Y., Sermanet, P., Reed, S., Anguelov, D., ... & Rabinovich, A. (2015). Going deeper with convolutions. In Proceedings of the IEEE conference on computer vision and pattern recognition (pp. 1-9).
  9. Sutskever, I., Vinyals, O., & Le, Q. V. (2014). Sequence to sequence learning with neural networks. In Advances in neural information processing systems (pp. 3104-3112).
  10. Ramsundar, B., Kearnes, S., Riley, P., Webster, D., Konerding, D., & Pande, V. (2015). Massively multitask networks for drug discovery. arXiv preprint arXiv:1502.02072
  11. Odena, A. (2016). Semi-supervised learning with generative adversarial networks. arXiv preprint arXiv:1606.01583.