Skip to content

liqilei/RCGAN

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

5 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Coupled GAN with Relativistic Discriminators for Infrared and Visible Images Fusion

This repository is for RCGAN presented in the following paper

Q. Li, L. Lu, Z. Li, et al., "Coupled GAN with Relativistic Discriminators for Infrared and Visible Images Fusion", IEEE SENSORS JOURNAL, 2019. [Link]

This code is tested on Ubuntu 16.04 environment (Python3.6, PyTorch1.1.0, CUDA9.0, cuDNN5.1) with NVIDIA 1080Ti/2080Ti GPU.

Contents

  1. Introduction
  2. Test
  3. Train
  4. Results
  5. Citation
  6. Acknowledgements

Introduction

Infrared and visible images are a pair of multi- source multi-sensors images. However, infrared image lack structural details and visible images are impressionable to the imaging environment. To fully utilize the meaningful information of infrared and visible images, a practical fusion method, termed as RCGAN, is proposed in this paper. In RCGAN, we introduce a pioneering use of the coupled generative adversarial network to the field of image fusion. Moreover, the simple yet efficient relativistic discriminator is applied to our network. By doing so, the network converges faster. More importantly, different from the previous works in which the label for generator is either infrared image or visible image, we innovatively put forward a strategy to use a pre-fused image as the label. This is a technical innovation, which makes the process of generating fused images no longer out of thin air, but from ‘existence’ to ‘excellent’. Extensive experiments demonstrate the effectiveness of our network compared with other state-of-the-art methods.

arch

Test

  1. The pre-trained model is placed in release folder. Modifyoptions/test/test_RCGAN.json to specify your own test options. Pay particular attention to the follow options: dataroot_VI: the path of visible dataset for test. dataroot_IR: the path of infrared dataset for test.

  2. Cd to the root folder and run the follow command: python test.py -opt options/test/test_RCGAN.json

    Then, bomb, you can get the Fused images in the ./release/results folder. Besides the ./release/cmp folder contains the the source images and fused images for a better comparison.

Train

Prepare training data

  1. Pre-fuse the infrared and visible images using GFF in ./preparation/1. GFF. Then, the pre-fused images will appear in ./Demo_dataset/train/ori_img/pf.
  2. Modify and run preparation/2. generate_train_data.py to crop the training data into patches. The default setting of the patches size is 120 * 120 and the stride is 14. After executing, a folder named ./Demo_dataset/train/sub_img can be obtained.

Specify the train options

Modifyoptions/train/train_RCGAN.json to specify your own train options. Pay particular attention to the follow options:

dataroot_VI the path of visible dataset for train or validation dataroot_IR: the path of infrared dataset for train or validation dataroot_PF: the path of pre-fused dataset for train or validation

More settings such as n_workers(threads), batch_size and other hy-parameters are set to default. You may modify them for your own sack.

Tips:

  1. resume option allows you to continue training your model even after the interruption. By setting set resume = true, the program will read the last saved check-point located in resume_path.

  2. We set 'data_type':'npy_reset' to speed up data reading during training. Since reading a numpy file is faster than reading an image file, we first transform PNG file to numpy file. This process is only performed once when the first time data is accessed.

  3. After performing above modifications, you can start training process by running python train.py -opt options/train/train_RCGAN.json. Then, you can get you model in experiment/*****/epoch/checkpoint.pth. You can also visualize the train loss and validation loss in results/results.csv.

Results

Visual Results

TNO

TNO

Quantitative Results

arch

For more results, please refer to our main papar

Citation

If you find the code helpful in your research or work, please cite our paper:

Q. Li et al., "Coupled GAN with Relativistic Discriminators for Infrared and Visible Images Fusion," in IEEE Sensors Journal.

Acknowledgements

This code is built on BasicSR. We thank the authors for sharing their codes.

About

Code for RCGAN publish in IEEE Sensors Journal

Resources

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published