"Gated Fusion Network for Joint Image Deblurring and Super-Resolution" by Xinyi Zhang, Hang Dong, Zhe Hu, Wei-Sheng Lai, Fei Wang, Ming-Hsuan Yang(oral presentation on BMVC2018).
There are more details you can find on Project Website : http://xinyizhang.tech/bmvc2018.
In order to obtain a more stable training process, now we adopt a three-step training strategy, which differs from our paper and improves PSNR from 27.74dB to 27.81dB on LR-GOPRO 4x dataset.
Model | LR-GOPRO 4x PSNR(dB) | Time(s) |
---|---|---|
SCGAN | 22.74 | 0.66 |
SRResNet | 24.40 | 0.07 |
ED-DSRN | 26.44 | 0.10 |
DeepDeblur + EDSR | 25.09 | 2.70 |
EDSR + DeepDeblur | 26.35 | 8.10 |
GFN(BMVC paper) | 27.74 | 0.07 |
GFN(Now) | 27.81 | 0.07 |
- Python 3.6
- PyTorch >= 0.4.0
- torchvision
- numpy
- skimage
- h5py
- MATLAB
This model is the result of the third step with 55 epoch.
- Git clone this repository.
$git clone https://github.com/jacquelinelala/GFN.git
$cd GFN
- Download the original GOPRO_Large dataset from Google Drive.
- Generate the validation images of LR-GOPRO dataset: Run matlab function
GFN/h5_generator/gopro_val_generator.m
. The generated test images will be stored in your_downloads_directory/GOPRO_Large/Validation_4x.
(If you don't have access to MATLAB, we offer a validation dataset for testing. You can download it from GoogleDrive or Pan Baidu.)
>> folder = 'your_downloads_directory/GOPRO_Large'; # You should replace the your_downloads_directory by your GOPRO_Large's directory.
>> gopro_val_generator(folder)
-
Download the trained model
GFN_epoch_55.pkl
from here, then unzip and move theGFN_epoch_55.pkl
toGFN/models
folder. -
Run the
GFN/test_GFN_x4.py
with cuda on command line:
GFN/$python test_GFN_x4.py --dataset your_downloads_directory/GOPRO_Large/Validation_4x
Then the deblurring and super-solving images ending with GFN_4x.png are in the directory of GOPRO_Large/Validation/Results.
- Calculate the PSNR using Matlab function
GFN/evaluation/test_RGB.m
. The output of the average PSNR is 27.810232 dB. You can also use theGFN/evaluation/test_bicubic.m
to calculate the bicubic method.
>> folder = 'your_downloads_directory/GOPRO_Large';
>> test_RGB(folder)
You should accomplish the first two steps in Test on LR-GOPRO Validation before the following steps.
- Generate the train hdf5 files of LR-GOPRO dataset: Run the matlab function
gopro_hdf5_generator.m
which is in the directory of GFN/h5_generator. The generated hdf5 files are stored in the your_downloads_directory/GOPRO_Large/GOPRO_train256_4x_HDF5.
>> folder = 'your_downloads_directory/GOPRO_Large';
>> gopro_hdf5_generator(folder)
- Run the
GFN/train_GFN_4x.py
with cuda on command line:
GFN/$python train_GFN_4x.py --dataset your_downloads_directory/GOPRO_Large/GOPRO_train256_4x_HDF5
- The three step intermediate models will be respectively saved in models/1/ models/2 and models/3. You can also use the following command to test the intermediate results during the training process.
Run the
GFN/test_GFN_x4.py
with cuda on command line:
GFN/$python test_GFN_x4.py --dataset your_downloads_directory/GOPRO_Large/Validation_4x --intermediate_process models/1/GFN_epoch_30.pkl # We give an example of step1 epoch30. You can replace another pkl file in models/.
Since the training process will take 3 or 4 days, you can use the following command to resume the training process from any breakpoints.
Run the GFN/train_GFN_4x.py
with cuda on command line:
GFN/$python train_GFN_4x.py --dataset your_downloads_directory/GOPRO_Large/GOPRO_train256_4x_HDF5 --resume models/1/GFN_epoch_30.pkl # Just an example of step1 epoch30.
If you use these models in your research, please cite:
@conference{Zhang2018,
author = {Xinyi Zhang and Hang Dong and Zhe Hu and Wei-Sheng Lai and Fei Wang and Ming-Hsuan Yang},
title = {Gated Fusion Network for Joint Image Deblurring and Super-Resolution},
booktitle = {BMVC},
year = {2018}
}