Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings

Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings

Collecting a large dataset of real infrared (IR) images is expensive, time-consuming, and even unavailable in some specific scenarios. With recent progress in machine learning, it has become more feasible to replace real IR images with qualified synthetic IR images in learning-based IR systems. Howe...

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Main Authors: Ruiheng Zhang, Chengpo Mu, Min Xu, Lixin Xu, Qiaolin Shi, Junbo Wang
Format: Article
Language:English
Published: IEEE 2019-01-01
Series:IEEE Access
Subjects:
Infrared simulation
synthetic refinement
convolutional neural networks
adversarial learning
Online Access:https://ieeexplore.ieee.org/document/8871125/
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spelling doaj-569dbc56f4ba4e76a8f11836c7a4a0aa2021-03-30T00:52:41ZengIEEEIEEE Access2169-35362019-01-01715373415375010.1109/ACCESS.2019.29476578871125Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional MappingsRuiheng Zhang0https://orcid.org/0000-0002-5460-7196Chengpo Mu1Min Xu2https://orcid.org/0000-0001-9581-8849Lixin Xu3Qiaolin Shi4Junbo Wang5School of Mechatronical Engineering, Beijing Institute of Technology, Beijing, ChinaSchool of Mechatronical Engineering, Beijing Institute of Technology, Beijing, ChinaGBDTC, Faculty of Engineering and IT, University of Technology Sydney, Ultimo, NSW, AustraliaSchool of Mechatronical Engineering, Beijing Institute of Technology, Beijing, ChinaGBDTC, Faculty of Engineering and IT, University of Technology Sydney, Ultimo, NSW, AustraliaBeijing Institute of Electronic System Engineering, Beijing, ChinaCollecting a large dataset of real infrared (IR) images is expensive, time-consuming, and even unavailable in some specific scenarios. With recent progress in machine learning, it has become more feasible to replace real IR images with qualified synthetic IR images in learning-based IR systems. However, this alternative may fail to achieve the desired performance, due to the gap between real and synthetic IR images. Inspired by adversarial learning for image-to-image translation, we propose the Synthetic IR Refinement Generative Adversarial Network (SIR-GAN) to narrow this gap. By learning the bidirectional mappings between two unpaired domains, the realism of the simulated IR images generated from the IR Simulator are significantly improved, where the source domain contains a large number of simulated IR images, where the target domain contains a limited quantity of real IR images. Specifically, driven by the idea of transferring infrared characteristic and protect target semantic information simultaneously, we propose a SIR refinement loss to consider an infrared loss and a structure loss further to the adversarial loss and the consistency loss. To further reduce the gap, stabilize training, and avoid artefacts, we modify the proposed algorithm by developing a training strategy, adding the U-net in the generators, using the dilated convolution in the discriminators and invoking the N-Adam acts as the optimizer. Qualitative, quantitative, and ablation study experiments demonstrate the superiority of the proposed approach compared with the state-of-the-art techniques in terms of realism and fidelity. In addition, our refined IR images are evaluated in the context of a feasibility study, where the accuracy of the trained classifier is significantly improved by adding our refined data into a small real-data training sethttps://ieeexplore.ieee.org/document/8871125/Infrared simulationsynthetic refinementconvolutional neural networksadversarial learning
collection DOAJ
language English
format Article
sources DOAJ
author Ruiheng Zhang
Chengpo Mu
Min Xu
Lixin Xu
Qiaolin Shi
Junbo Wang
spellingShingle Ruiheng Zhang
Chengpo Mu
Min Xu
Lixin Xu
Qiaolin Shi
Junbo Wang
Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
IEEE Access
Infrared simulation
synthetic refinement
convolutional neural networks
adversarial learning
author_facet Ruiheng Zhang
Chengpo Mu
Min Xu
Lixin Xu
Qiaolin Shi
Junbo Wang
author_sort Ruiheng Zhang
title Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
title_short Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
title_full Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
title_fullStr Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
title_full_unstemmed Synthetic IR Image Refinement Using Adversarial Learning With Bidirectional Mappings
title_sort synthetic ir image refinement using adversarial learning with bidirectional mappings
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2019-01-01
description Collecting a large dataset of real infrared (IR) images is expensive, time-consuming, and even unavailable in some specific scenarios. With recent progress in machine learning, it has become more feasible to replace real IR images with qualified synthetic IR images in learning-based IR systems. However, this alternative may fail to achieve the desired performance, due to the gap between real and synthetic IR images. Inspired by adversarial learning for image-to-image translation, we propose the Synthetic IR Refinement Generative Adversarial Network (SIR-GAN) to narrow this gap. By learning the bidirectional mappings between two unpaired domains, the realism of the simulated IR images generated from the IR Simulator are significantly improved, where the source domain contains a large number of simulated IR images, where the target domain contains a limited quantity of real IR images. Specifically, driven by the idea of transferring infrared characteristic and protect target semantic information simultaneously, we propose a SIR refinement loss to consider an infrared loss and a structure loss further to the adversarial loss and the consistency loss. To further reduce the gap, stabilize training, and avoid artefacts, we modify the proposed algorithm by developing a training strategy, adding the U-net in the generators, using the dilated convolution in the discriminators and invoking the N-Adam acts as the optimizer. Qualitative, quantitative, and ablation study experiments demonstrate the superiority of the proposed approach compared with the state-of-the-art techniques in terms of realism and fidelity. In addition, our refined IR images are evaluated in the context of a feasibility study, where the accuracy of the trained classifier is significantly improved by adding our refined data into a small real-data training set
topic Infrared simulation
synthetic refinement
convolutional neural networks
adversarial learning
url https://ieeexplore.ieee.org/document/8871125/
work_keys_str_mv AT ruihengzhang syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
AT chengpomu syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
AT minxu syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
AT lixinxu syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
AT qiaolinshi syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
AT junbowang syntheticirimagerefinementusingadversariallearningwithbidirectionalmappings
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