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Pretrained BigBiGAN models

We have released pretrained BigBiGAN models used for unsupervised image generation and representation learning, as described in our July 2019 tech report, "Large Scale Adversarial Representation Learning" [1].

The pretrained models are available for use via TF Hub. The release includes two BigBiGAN models with different encoder architectures:

See the TF Hub pages linked above for documentation and example usage of each module.

Demo (Colab)

A Google Colab-based demo with example usage of the model functionality and sample visualization is available here.

Example use

The snippet below demonstrates the use of the released TF Hub modules for image generation/reconstruction and encoder feature computation. (The Colab demo includes more extensive documentation and visualizations.)

# Load BigBiGAN module.
module = hub.Module('https://tfhub.dev/deepmind/bigbigan-resnet50/1')  # small encoder
# module = hub.Module('https://tfhub.dev/deepmind/bigbigan-revnet50x4/1')  # large encoder

# Sample a batch of 8 random latent vectors (z) from the Gaussian prior. Then
# call the generator on the latent samples to generate a batch of images with
# shape [8, 128, 128, 3] and range [-1, 1].
z = tf.random.normal([8, 120])  # latent samples
gen_samples = module(z, signature='generate')

# Given a batch of 256x256 RGB images in range [-1, 1], call the encoder to
# compute predicted latents z and other features (e.g. for use in downstream
# recognition tasks).
images = tf.placeholder(tf.float32, shape=[None, 256, 256, 3])
features = module(images, signature='encode', as_dict=True)

# Get the predicted latent sample `z_sample` from the dict of features.
# Other available features include `avepool_feat` and `bn_crelu_feat`, used in
# the representation learning results.
z_sample = features['z_sample']  # shape [?, 120]

# Compute reconstructions of the input `images` by passing the encoder's output
# `z_sample` back through the generator. Note that raw generator outputs are
# half the resolution of encoder inputs (128x128). To get upsampled generator
# outputs matching the encoder input resolution (256x256), instead use:
#     recons = module(z_sample, signature='generate', as_dict=True)['upsampled']
recons = module(z_sample, signature='generate')  # shape [?, 128, 128, 3]

References

[1] Jeff Donahue and Karen Simonyan. Large Scale Adversarial Representation Learning. arxiv:1907.02544, 2019.