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1 Super Resolution

1.1 Principle

Super resolution is a process of upscaling and improving the details within an image. It usually takes a low-resolution image as input and upscales the same image to a higher resolution as output. Here we provide three super-resolution models, namely RealSR, ESRGAN, LESRCNN.

RealSR focus on designing a novel degradation framework for realworld images by estimating various blur kernels as well as real noise distributions. Based on the novel degradation framework, we can acquire LR images sharing a common domain with real-world images. RealSR is a real-world super-resolution model aiming at better perception. Extensive experiments on synthetic noise data and real-world images demonstrate that RealSR outperforms the state-of-the-art methods, resulting in lower noise and better visual quality.

ESRGAN is an enhanced SRGAN. To further enhance the visual quality of SRGAN, ESRGAN improves three key components of srgan. In addition, ESRGAN also introduces the Residual-in-Residual Dense Block (RRDB) without batch normalization as the basic network building unit, lets the discriminator predict relative realness instead of the absolute value, and improves the perceptual loss by using the features before activation. Benefiting from these improvements, the proposed ESRGAN achieves consistently better visual quality with more realistic and natural textures than SRGAN and won the first place in the PIRM2018-SR Challenge.

Considering that the application of CNN in SISR often consume high computational cost and more memory storage for training a SR model, a lightweight enhanced SR CNN (LESRCNN) was proposed.Extensive experiments demonstrate that the proposed LESRCNN outperforms state-of-the-arts on SISR in terms of qualitative and quantitative evaluation.

1.2 How to use

1.2.1 Prepare Datasets

A list of common image super-resolution datasets is as following:

Name Datasets Short Description Download
2K Resolution DIV2K proposed in NTIRE17 (800 train and 100 validation) official website
Classical SR Testing Set5 Set5 test dataset Google Drive / Baidu Drive
Classical SR Testing Set14 Set14 test dataset Google Drive / Baidu Drive

The structure of DIV2K, Set5 and Set14 is as following:

  PaddleGAN
    ├── data
        ├── DIV2K
              ├── DIV2K_train_HR
              ├── DIV2K_train_LR_bicubic
              |    ├──X2
              |    ├──X3
              |    └──X4
              ├── DIV2K_valid_HR
              ├── DIV2K_valid_LR_bicubic
            Set5
              ├── GTmod12
              ├── LRbicx2
              ├── LRbicx3
              ├── LRbicx4
              └── original
            Set14
              ├── GTmod12
              ├── LRbicx2
              ├── LRbicx3
              ├── LRbicx4
              └── original
            ...

Use the following commands to process the DIV2K data set:

  python data/process_div2k_data.py --data-root data/DIV2K

When the program is finished, check whether there are DIV2K_train_HR_sub, X2_sub, X3_sub and X4_sub directories in the DIV2K directory

  PaddleGAN
    ├── data
        ├── DIV2K
              ├── DIV2K_train_HR
              ├── DIV2K_train_HR_sub
              ├── DIV2K_train_LR_bicubic
              |    ├──X2
              |    ├──X2_sub
              |    ├──X3
              |    ├──X3_sub
              |    ├──sX4
              |    └──X4_sub
              ├── DIV2K_valid_HR
              ├── DIV2K_valid_LR_bicubic
            ...

Prepare dataset for realsr df2k model

Download dataset from NTIRE 2020 RWSR and unzip it to your path. Unzip Corrupted-tr-x.zip and Corrupted-tr-y.zip to PaddleGAN/data/ntire20 directory.

Run the following commands:

  python ./data/realsr_preprocess/create_bicubic_dataset.py --dataset df2k --artifacts tdsr

  python ./data/realsr_preprocess/collect_noise.py --dataset df2k --artifacts tdsr

Prepare dataset for realsr dped model

Download dataset from NTIRE 2020 RWSR and unzip it to your path. Unzip DPEDiphone-tr-x.zip and DPEDiphone-va.zip to PaddleGAN/data/ntire20 directory.

Use KernelGAN to generate kernels from source images. Clone the repo here. Replace SOURCE_PATH with specific path and run:

python train.py --X4 --input-dir SOURCE_PATH

for convenient, we provide DPED_KERNEL.tar. You can download it to PaddleGAN/data/DPED_KERNEL

Run the following commands:

  python ./data/realsr_preprocess/create_kernel_dataset.py --dataset dped --artifacts clean --kernel_path data/DPED_KERNEL
  python ./data/realsr_preprocess/collect_noise.py --dataset dped --artifacts clean

1.2.2 Train/Test

Datasets used in example is df2k, you can change it to your own dataset in the config file. The model used in example is RealSR, you can change other models by replacing the config file.

Train a model:

   python -u tools/main.py --config-file configs/realsr_bicubic_noise_x4_df2k.yaml

Test the model:

   python tools/main.py --config-file configs/realsr_bicubic_noise_x4_df2k.yaml --evaluate-only --load ${PATH_OF_WEIGHT}

1.3 Results

Evaluated on RGB channels, scale pixels in each border are cropped before evaluation.

The metrics are PSNR / SSIM.

Method Set5 Set14 DIV2K
realsr_df2k 28.4385 / 0.8106 24.7424 / 0.6678 26.7306 / 0.7512
realsr_dped 20.2421 / 0.6158 19.3775 / 0.5259 20.5976 / 0.6051
realsr_merge 24.8315 / 0.7030 23.0393 / 0.5986 24.8510 / 0.6856
lesrcnn_x4 31.9476 / 0.8909 28.4110 / 0.7770 30.231 / 0.8326
esrgan_psnr_x4 32.5512 / 0.8991 28.8114 / 0.7871 30.7565 / 0.8449
esrgan_x4 28.7647 / 0.8187 25.0065 / 0.6762 26.9013 / 0.7542
drns_x4 32.6684 / 0.8999 28.9037 / 0.7885 -

1.4 模型下载

模型 数据集 下载地址
realsr_df2k df2k realsr_df2k
realsr_dped dped realsr_dped
realsr_merge DIV2K realsr_merge
lesrcnn_x4 DIV2K lesrcnn_x4
esrgan_psnr_x4 DIV2K esrgan_psnr_x4
esrgan_x4 DIV2K esrgan_x4
drns_x4 DIV2K drns_x4

References

    1. Real-World Super-Resolution via Kernel Estimation and Noise Injection
    @inproceedings{ji2020real,
    title={Real-World Super-Resolution via Kernel Estimation and Noise Injection},
    author={Ji, Xiaozhong and Cao, Yun and Tai, Ying and Wang, Chengjie and Li, Jilin and Huang, Feiyue},
    booktitle={Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition Workshops},
    pages={466--467},
    year={2020}
    }
    
    1. ESRGAN: Enhanced Super-Resolution Generative Adversarial Networks
    @inproceedings{wang2018esrgan,
    title={Esrgan: Enhanced super-resolution generative adversarial networks},
    author={Wang, Xintao and Yu, Ke and Wu, Shixiang and Gu, Jinjin and Liu, Yihao and Dong, Chao and Qiao, Yu and Change Loy, Chen},
    booktitle={Proceedings of the European Conference on Computer Vision (ECCV)},
    pages={0--0},
    year={2018}
    }
    
    1. Lightweight image super-resolution with enhanced CNN
    @article{tian2020lightweight,
    title={Lightweight image super-resolution with enhanced CNN},
    author={Tian, Chunwei and Zhuge, Ruibin and Wu, Zhihao and Xu, Yong and Zuo, Wangmeng and Chen, Chen and Lin, Chia-Wen},
    journal={Knowledge-Based Systems},
    volume={205},
    pages={106235},
    year={2020},
    publisher={Elsevier}
    }
    
    1. Closed-loop Matters: Dual Regression Networks for Single Image Super-Resolution
    @inproceedings{guo2020closed,
    title={Closed-loop Matters: Dual Regression Networks for Single Image Super-Resolution},
    author={Guo, Yong and Chen, Jian and Wang, Jingdong and Chen, Qi and Cao, Jiezhang and Deng, Zeshuai and Xu, Yanwu and Tan, Mingkui},
    booktitle={Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition},
    year={2020}
    }