| Vanilla GAN on MNIST | Deep Convolutional GAN on MNIST |
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| Vanilla GAN on CIFAR | Deep Convolutional GAN on CIFAR |
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Our Vanilla GAN are just Multi-Layer Perceptrons (linear transformations followed by ReLU nonlinearities). CIFAR's Vanilla model has more layers than MNIST; and Generator has more layers than Discriminators. For DCGAN, Generator and Discriminator in both MNIST and CIFAR have deep convolutional structures. The parameters for MNIST's both model is taken from InfoGAN (Chen et al.). CIFAR's model is similar to MNIST's only deeper.
To reproduce our results, first run $ jupyter notebook and copy over the following setup code:
Note: if you run on a CPU please change the dtype to torch.FloatTensor (uncomment the last line). However,
beware that our model includes deep convolutional networks that would run extremely slow on CPU.
import GAN
import GAN.MNIST.GAN, GAN.MNIST.DCGAN
import GAN.CIFAR.GAN, GAN.CIFAR.DCGAN
from GAN.utils import *
from dataloader import *
import matplotlib.pyplot as plt
%matplotlib inline
plt.rcParams['image.interpolation'] = 'nearest'
plt.rcParams['image.cmap'] = 'gray'
mnist_loader, cifar_loader = get_data()
dtype = torch.cuda.FloatTensor
# dtype = torch.FloatTensorTo train a model and see the pictures for yourself, you could run the following code to train a vanilla GAN (Goodfellow et al.) on MNIST dataset:
D = GAN.MNIST.GAN.get_discriminator().type(dtype)
G = GAN.MNIST.GAN.get_generator().type(dtype)
D_optim = GAN.utils.get_optimizer(D)
G_optim = GAN.utils.get_optimizer(G)
GAN.MNIST.train(D, G, D_optim, G_optim, discriminator_loss,
generator_loss, dtype, mnist_loader)To switch to CIFAR dataset, change all MNIST to CIFAR would do the trick. To switch to Deep Convolutional GAN (i.e., DCGAN, Radford et al.),
use GAN.MNIST.DCGAN instead in the first two lines (you could also do CIFAR).
- X. Chen, Y. Duan, R. Houthooft, J. Schulman, I. Sutskever, and P. Abbeel. "Infogan: Interpretable representation learning by information maximizing generative adversarial nets", in NIPS, 2016.
- I. Goodfellow, J. Pouget-Abdie, M.Mirza, B. Xu, D. Warde-Farley, S.Ozair, A. Courville, and Y. Bengio, "Generative Adversarial Nets", in NIPS, 2014, pp.2672-2680.
- A. Radford, L. Metz, and S. Chintala, "Unsupervised Representation Learning with Deep Convolutional Generative Adversarial Networks", in ICLR, 2016.