Skip to content

πŸ”Ž Super-scale your images and run experiments with Residual Dense and Adversarial Networks.

License

Notifications You must be signed in to change notification settings

tom00/image-super-resolution

Β 
Β 

Repository files navigation

Image Super-Resolution (ISR)

Build Status Docs License

The goal of this project is to upscale and improve the quality of low resolution images.

This project contains Keras implementations of different Residual Dense Networks for Single Image Super-Resolution (ISR) as well as scripts to train these networks using content and adversarial loss components.

The implemented networks include:

Read the full documentation at: https://idealo.github.io/image-super-resolution/.

Docker scripts and Google Colab notebooks are available to carry training and prediction. Also, we provide scripts to facilitate training on the cloud with AWS and nvidia-docker with only a few commands.

ISR is compatible with Python 3.6 and is distributed under the Apache 2.0 license. We welcome any kind of contribution. If you wish to contribute, please see the Contribute section.

Contents

Pre-trained networks

The weights used to produced these images are available directly when creating the model object.

Currently 4 models are available:

  • RDN: psnr-large, psnr-small, noise-cancel
  • RRDN: gans

Example usage:

model = RRDN(weights='gans')

The network parameters will be automatically chosen. (see Additional Information).

Basic model

RDN model, PSNR driven, choose the option weights='psnr-large' or weights='psnr-small' when creating a RDN model.

butterfly-sample
Low resolution image (left), ISR output (center), bicubic scaling (right). Click to zoom.

GANS model

RRDN model, trained with Adversarial and VGG features losses, choose the option weights='gans' when creating a RRDN model.

baboon-comparison
RRDN GANS model (left), bicubic upscaling (right).
-> more detailed comparison

Artefact Cancelling GANS model

RDN model, trained with Adversarial and VGG features losses, choose the option weights='noise-cancel' when creating a RDN model.

temple-comparison
Standard vs GANS model. Click to zoom.
sandal-comparison
RDN GANS artefact cancelling model (left), RDN standard PSNR driven model (right).
-> more detailed comparison

Installation

There are two ways to install the Image Super-Resolution package:

  • Install ISR from PyPI (recommended):
pip install ISR
  • Install ISR from the GitHub source:
git clone https://github.com/idealo/image-super-resolution
cd image-super-resolution
python setup.py install

Usage

Prediction

Load image and prepare it

import numpy as np
from PIL import Image

img = Image.open('data/input/test_images/sample_image.jpg')
lr_img = np.array(img)

Load a pre-trained model and run prediction (check the prediction tutorial under notebooks for more details)

from ISR.models import RDN

rdn = RDN(weights='psnr-small')
sr_img = rdn.predict(lr_img)
Image.fromarray(sr_img)

Large image inference

To predict on large images and avoid memory allocation errors, use the by_patch_of_size option for the predict method, for instance

sr_img = model.predict(image, by_patch_of_size=50)

Check the documentation of the ImageModel class for further details.

Training

Create the models

from ISR.models import RRDN
from ISR.models import Discriminator
from ISR.models import Cut_VGG19

lr_train_patch_size = 40
layers_to_extract = [5, 9]
scale = 2
hr_train_patch_size = lr_train_patch_size * scale

rrdn  = RRDN(arch_params={'C':4, 'D':3, 'G':64, 'G0':64, 'T':10, 'x':scale}, patch_size=lr_train_patch_size)
f_ext = Cut_VGG19(patch_size=hr_train_patch_size, layers_to_extract=layers_to_extract)
discr = Discriminator(patch_size=hr_train_patch_size, kernel_size=3)

Create a Trainer object using the desired settings and give it the models (f_ext and discr are optional)

from ISR.train import Trainer
loss_weights = {
  'generator': 0.0,
  'feature_extractor': 0.0833,
  'discriminator': 0.01
}
losses = {
  'generator': 'mae',
  'feature_extractor': 'mse',
  'discriminator': 'binary_crossentropy'
}

log_dirs = {'logs': './logs', 'weights': './weights'}

learning_rate = {'initial_value': 0.0004, 'decay_factor': 0.5, 'decay_frequency': 30}

flatness = {'min': 0.0, 'max': 0.15, 'increase': 0.01, 'increase_frequency': 5}

trainer = Trainer(
    generator=rrdn,
    discriminator=discr,
    feature_extractor=f_ext,
    lr_train_dir='low_res/training/images',
    hr_train_dir='high_res/training/images',
    lr_valid_dir='low_res/validation/images',
    hr_valid_dir='high_res/validation/images',
    loss_weights=loss_weights,
    learning_rate=learning_rate,
    flatness=flatness,
    dataname='image_dataset',
    log_dirs=log_dirs,
    weights_generator=None,
    weights_discriminator=None,
    n_validation=40,
)

Start training

trainer.train(
    epochs=80,
    steps_per_epoch=500,
    batch_size=16,
    monitored_metrics={'val_PSNR_Y': 'max'}
)

Additional Information

You can read about how we trained these network weights in our Medium posts:

RDN Pre-trained weights

The weights of the RDN network trained on the DIV2K dataset are available in weights/sample_weights/rdn-C6-D20-G64-G064-x2/PSNR-driven/rdn-C6-D20-G64-G064-x2_PSNR_epoch086.hdf5.
The model was trained using C=6, D=20, G=64, G0=64 as parameters (see architecture for details) for 86 epochs of 1000 batches of 8 32x32 augmented patches taken from LR images.

The artefact can cancelling weights obtained with a combination of different training sessions using different datasets and perceptual loss with VGG19 and GAN can be found at weights/sample_weights/rdn-C6-D20-G64-G064-x2/ArtefactCancelling/rdn-C6-D20-G64-G064-x2_ArtefactCancelling_epoch219.hdf5 We recommend using these weights only when cancelling compression artefacts is a desirable effect.

RDN Network architecture

The main parameters of the architecture structure are:

  • D - number of Residual Dense Blocks (RDB)
  • C - number of convolutional layers stacked inside a RDB
  • G - number of feature maps of each convolutional layers inside the RDBs
  • G0 - number of feature maps for convolutions outside of RDBs and of each RBD output


source: Residual Dense Network for Image Super-Resolution

RRDN Network architecture

The main parameters of the architecture structure are:

  • T - number of Residual in Residual Dense Blocks (RRDB)
  • D - number of Residual Dense Blocks (RDB) insider each RRDB
  • C - number of convolutional layers stacked inside a RDB
  • G - number of feature maps of each convolutional layers inside the RDBs
  • G0 - number of feature maps for convolutions outside of RDBs and of each RBD output


source: ESRGAN: Enhanced Super-Resolution Generative Adversarial Networks

Contribute

We welcome all kinds of contributions, models trained on different datasets, new model architectures and/or hyperparameters combinations that improve the performance of the currently published model.

Will publish the performances of new models in this repository.

See the Contribution guide for more details.

Bump version

To bump up the version, use

bumpversion {part} setup.py

Citation

Please cite our work in your publications if it helps your research.

@misc{cardinale2018isr,
  title={ISR},
  author={Francesco Cardinale et al.},
  year={2018},
  howpublished={\url{https://github.com/idealo/image-super-resolution}},
}

Maintainers

Copyright

See LICENSE for details.

About

πŸ”Ž Super-scale your images and run experiments with Residual Dense and Adversarial Networks.

Resources

License

Stars

Watchers

Forks

Packages

No packages published

Languages

  • Python 99.9%
  • Shell 0.1%