Realistic Blur Synthesis for Learning Image Deblurring
Jaesung Rim, Geonung Kim, Jungeon Kim, Junyong Lee, Seungyong Lee, Sunghyun Cho.
POSTECH
IEEE European Conference on Computer Vision (ECCV) 2022
We provide simple Dataset modules for adopting our pipeline. This is slightly different from the tensorflow implementation.
Please refer to Uformer-RSBlur.
# ./Uformer-RSBlur/dataset/dataset_RealisticDeblur.py
class RealisticGoProABMEDataset(Dataset):
def __init__(self, image_dir, patch_size=256, image_aug=True, realistic_pipeline=True):
...
def __len__(self):
return len(self.image_list)
def __getitem__(self, idx):
...
class RealisticGoProUDataset(Dataset):
def __init__(self, image_dir, patch_size=256, image_aug=True, realistic_pipeline=True):
...
def __len__(self):
return len(self.image_list)
def __getitem__(self, idx):
...
Results of analysis (click)
CRF | Interp. | Sat. | Noise | ISP | PSNR / SSIM |
---|---|---|---|---|---|
Linear | 30.12 / 0.7727 | ||||
sRGB | 30.90 / 0.7805 | ||||
sRGB | ✓ | 30.20 / 0.7468 | |||
sRGB | ✓ | G | 31.77 / 0.8275 | ||
sRGB | ✓ | Ours | G | 31.83 / 0.8265 | |
sRGB | ✓ | Ours | G+P | ✓ | 32.06 / 0.8322 |
git clone https://github.com/rimchang/RSBlur.git
We recommend a virtual environment using conda or docker.
- Tensorflow 1.15
- cuda11.1
Dataset [Google Drive] [Postech]
Descriptions (click)
- RSBlur
- 13,358 pairs of real/synthetic blurred image and a corresponding GT image.
- RSBlur_additional
- 8,821 additional images for learning based synthesis, additional synthetic images or etc.
- Do not use it as additional real training images.
- RSBlur_sharps
- All of sharp image sequneces.
- GoPro_INTER_ABME
- Synthetic blur dataset using GoPro and ABME method.
- GoPro_U
- Synthetic blur dataset using GoPro and synthetic blur kernels.
# RSBlur.zip
RSBlur
├── 0001
│ ├── 000001
│ │ ├── real_blur/real_blur.png # real blurred image
│ │ ├── avg65_img/avg_blur.png # synthetic blurred image using frame interpolation
│ │ ├── avg65_mask_100/avg_blur.png # saturation mask
│ │ ├── gt/gt_sharp.png # ground truth sharp image
...
# GoPro_INTER_ABME.zip
GoPro_INTER_ABME
├── GOPR0372_07_00
│ ├── 000001
│ │ ├── avg_inter_img/avg_blur.png # synthetic blurred image using frame interpolation
│ │ ├── avg_inter_mask_100/avg_blur.png # saturation mask
│ │ ├── gt/gt_sharp.png # ground truth sharp image
...
# GoPro_U.zip
GoPro_U
├── centroid_blurred_img
│ ├── 0_GOPR0372_07_00_000047_003754_kernel_25_blurred.png # synthetic blurred image using a synthetic blur kernel
│ ...
├── centroid_blurred_mask_100
│ ├── 0_GOPR0372_07_00_000047_003754_kernel_25_blurred.png # saturation mask
│ ...
├── target_img
│ ├── 0_GOPR0372_07_00_000047_003754_kernel_25_gt.png # ground truth sharp image
│ ...
Dataset splits [link]
Pre-trained models [Google Drive] [Postech]
Descriptions (click)
- SRN-Deblur_RSBlur_real : Trained on real set of RSBlur.
- SRN-Deblur_RSBlur_syn_with_ours : Trained on synthetic set of RSBlur with our synthesis pipeline.
- SRN-Deblur_GoPro_ABME_with_ours : Trained on GoPro_INTER_ABME with our synthesis pipeline.
- SRN-Deblur_GoPro_U_with_ours : Trained on GoPro_U with our synthesis pipeline.
# ./SRN-Deblur-RSBlur
# All datasets should be located in SRN-Deblur-RSBlur/dataset
# RSBlur
python run_model.py --phase=train --checkpoint_path=0719_SRN-Deblur_RSBlur_real --sat_synthesis=None --noise_synthesis=None --datalist=../datalist/RSBlur/RSBlur_real_train.txt --gpu=0
python run_model.py --phase=train --checkpoint_path=0719_SRN-Deblur_RSBlur_syn_with_ours --sat_synthesis=sat_synthesis --noise_synthesis=poisson_RSBlur --cam_params_RSBlur=1 --datalist=../datalist/RSBlur/RSBlur_syn_train.txt --gpu=0
# GoPro_INTER_ABME
python run_model.py --phase=train --checkpoint_path=0719_SRN-Deblur_GoPro_ABME_with_ours --target_dataset=RealBlur --sat_synthesis=sat_synthesis --noise_synthesis=poisson_gamma --cam_params_RealBlur=1 --adopt_crf_realblur=1 --datalist=../datalist/GoPro/GoPro_INTER_ABME_train.txt --gpu=0
# GoPro_U
python run_model.py --phase=train --checkpoint_path=0719_SRN-Deblur_U_with_ours --target_dataset=RealBlur --sat_synthesis=sat_synthesis --noise_synthesis=poisson_gamma --cam_params_RealBlur=1 --adopt_crf_realblur=1 --datalist=../datalist/GoPro/GoPro_U_train.txt --gpu=0
# ./SRN-Deblur-RSBlur
# All datasets should be located in SRN-Deblur-RSBlur/dataset
# RSBlur
python run_model.py --phase=test --checkpoint_path=SRN-Deblur_RSBlur_real --datalist=../datalist/RSBlur/RSBlur_real_test.txt --gpu=0
python run_model.py --phase=test --checkpoint_path=SRN-Deblur_RSBlur_syn_with_ours --datalist=../datalist/RSBlur/RSBlur_real_test.txt --gpu=0
# RealBlur
python run_model.py --phase=test --checkpoint_path=SRN-Deblur_GoPro_ABME_with_ours --datalist=../datalist/RealBlur_J_test_list.txt --gpu=0
python run_model.py --phase=test --checkpoint_path=SRN-Deblur_GoPro_U_with_ours --datalist=../datalist/RealBlur_J_test_list.txt --gpu=0
# ./evaluation
python evaluate_RSBlur.py --input_dir=../SRN-Deblur-RSBlur/testing_res/SRN-Deblur_RSBlur_real --gt_root=../SRN-Deblur-RSBlur/dataset/RSBlur;
python evaluate_RealBlur.py --input_dir=../SRN-Deblur-RSBlur/testing_res/SRN-Deblur_U_with_ours --gt_root=../SRN-Deblur-RSBlur/dataset/RealBlur-J_ECC_IMCORR_centroid_itensity_ref;
We provide an additional deblurring benchmark to provide the basis for future deblurring research. All below models are trained on real blurred images of the RSBlur training set.
Results of benchmark (click)
Methods | PSNR / SSIM | Link |
---|---|---|
Uformer-B | 33.98 / 0.8660 | Result / Weight / Test Code |
Restormer | 33.69 / 0.8628 | Result / Weight |
MPRNet | 33.61 / 0.8614 | Result / Weight |
MiMO-UNet+ | 33.37 / 0.8560 | Result / Weight |
MiMO-UNet | 32.73 / 0.8457 | Result / Weight |
SRN-Deblur | 32.53 / 0.8398 | Result / Weight |
The RSBlur dataset is released under CC BY 4.0 license.
The code is based on SRN-Deblur, CBDNet and UID.
If you use our dataset for your research, please cite our paper.
@inproceedings{rim_2022_ECCV,
title={Realistic Blur Synthesis for Learning Image Deblurring},
author={Rim, Jaesung and Kim, Geonung and Kim, Jungeon and Lee, Junyong and Lee, Seungyong and Cho, Sunghyun},
booktitle={Proceedings of the European Conference on Computer Vision (ECCV)},
year={2022}
}