基于深度残差学习的移相干涉图盲去噪

IF 0.7 4区 物理与天体物理 Q4 OPTICS
Optica Applicata Pub Date : 2022-01-01 DOI:10.37190/oa220108
Xiaoqing Xu, Ming Xie, Song Chen, Ying Ji, Yawei Wang
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引用次数: 0

摘要

含有噪声的干涉图往往会影响相位恢复的精度,导致相位成像质量的下降。针对这一问题,提出了一种基于深度残差学习的干涉图盲去噪方法。在存在未知噪声水平的情况下,IBD方法中的深度残差卷积神经网络(DRCNN)在训练过程中能够隐式去除潜在的干净干涉图,然后在像素级上逐渐建立干涉图与噪声之间的残差映射关系。该算法通过训练良好的DRCNN模型,既能高效处理单帧干涉图,又能协同处理多帧相移干涉图,同时有效保留与相位恢复相关的干涉图特征。仿真和实验结果验证了该方法的可行性和适用性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Interferogram blind denoising using deep residual learning for phase-shifting interferometry
The interferogram containing the noises often affects the accuracy of phase retrieval, leading to the degradation of the phase imaging quality. To address this issue, a new interferogram blind denoising (IBD) method based on deep residual learning is proposed. In the presence of unknown noise levels, during the training, the deep residual convolutional neural networks (DRCNN) in the IBD approach is able to remove the latent clean interferogram implicitly, and then gradually establish the residual mapping relation in the pixel-level between the interferogram and the noises. With a well-trained DRCNN model, this algorithm can deal not only with the single-frame interferogram efficiently but also with the multi-frame phase-shifted interferograms collaboratively, while effectively retaining interferogram features related to phase retrieval. Simulation and experimental results demonstrate the feasibility and applicability of the proposed IBD method.
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来源期刊
Optica Applicata
Optica Applicata 物理-光学
CiteScore
1.00
自引率
16.70%
发文量
21
审稿时长
4 months
期刊介绍: Acoustooptics, atmospheric and ocean optics, atomic and molecular optics, coherence and statistical optics, biooptics, colorimetry, diffraction and gratings, ellipsometry and polarimetry, fiber optics and optical communication, Fourier optics, holography, integrated optics, lasers and their applications, light detectors, light and electron beams, light sources, liquid crystals, medical optics, metamaterials, microoptics, nonlinear optics, optical and electron microscopy, optical computing, optical design and fabrication, optical imaging, optical instrumentation, optical materials, optical measurements, optical modulation, optical properties of solids and thin films, optical sensing, optical systems and their elements, optical trapping, optometry, photoelasticity, photonic crystals, photonic crystal fibers, photonic devices, physical optics, quantum optics, slow and fast light, spectroscopy, storage and processing of optical information, ultrafast optics.
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