Noniterative spatially partially coherent diffractive imaging using pinhole array mask

Xingyuan Lu; Yifeng Shao; Chengliang Zhao; Sander Konijnenberg; Xinlei Zhu; Ying Tang; Yangjian Cai; H. Paul Urbach

doi:10.1117/1.AP.1.1.016005

Noniterative spatially partially coherent diffractive imaging using pinhole array mask

Xingyuan Lu, Yifeng Shao, Chengliang Zhao^*, Sander Konijnenberg, Xinlei Zhu, Ying Tang, Yangjian Cai, H. Paul Urbach

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

We propose and experimentally demonstrate a noniterative diffractive imaging method for reconstructing the complex-valued transmission function of an object illuminated by spatially partially coherent light from the far-field diffraction pattern. Our method is based on a pinhole array mask, which is specially designed such that the correlation function in the mask plane can be obtained directly by inverse Fourier transforming the diffraction pattern. Compared to the traditional iterative diffractive imaging methods using spatially partially coherent illumination, our method is noniterative and robust to the degradation of the spatial coherence of the illumination. In addition to diffractive imaging, the proposed method can also be applied to spatial coherence property characterization, e.g., free-space optical communication and optical coherence singularity measurement.

Original language	English
Article number	016005
Number of pages	8
Journal	Advanced Photonics
Volume	1
Issue number	1
DOIs	https://doi.org/10.1117/1.AP.1.1.016005
Publication status	Published - 2019

Keywords

coherent diffractive imaging
noniterative method
partial coherence
pinhole array mask

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10.1117/1.AP.1.1.016005

016005_1Final published version, 2.57 MBLicence: CC BY

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title = "Noniterative spatially partially coherent diffractive imaging using pinhole array mask",

abstract = "We propose and experimentally demonstrate a noniterative diffractive imaging method for reconstructing the complex-valued transmission function of an object illuminated by spatially partially coherent light from the far-field diffraction pattern. Our method is based on a pinhole array mask, which is specially designed such that the correlation function in the mask plane can be obtained directly by inverse Fourier transforming the diffraction pattern. Compared to the traditional iterative diffractive imaging methods using spatially partially coherent illumination, our method is noniterative and robust to the degradation of the spatial coherence of the illumination. In addition to diffractive imaging, the proposed method can also be applied to spatial coherence property characterization, e.g., free-space optical communication and optical coherence singularity measurement. ",

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T1 - Noniterative spatially partially coherent diffractive imaging using pinhole array mask

AU - Lu, Xingyuan

AU - Shao, Yifeng

AU - Zhao, Chengliang

AU - Konijnenberg, Sander

AU - Zhu, Xinlei

AU - Tang, Ying

AU - Cai, Yangjian

AU - Urbach, H. Paul

PY - 2019

Y1 - 2019

N2 - We propose and experimentally demonstrate a noniterative diffractive imaging method for reconstructing the complex-valued transmission function of an object illuminated by spatially partially coherent light from the far-field diffraction pattern. Our method is based on a pinhole array mask, which is specially designed such that the correlation function in the mask plane can be obtained directly by inverse Fourier transforming the diffraction pattern. Compared to the traditional iterative diffractive imaging methods using spatially partially coherent illumination, our method is noniterative and robust to the degradation of the spatial coherence of the illumination. In addition to diffractive imaging, the proposed method can also be applied to spatial coherence property characterization, e.g., free-space optical communication and optical coherence singularity measurement.

AB - We propose and experimentally demonstrate a noniterative diffractive imaging method for reconstructing the complex-valued transmission function of an object illuminated by spatially partially coherent light from the far-field diffraction pattern. Our method is based on a pinhole array mask, which is specially designed such that the correlation function in the mask plane can be obtained directly by inverse Fourier transforming the diffraction pattern. Compared to the traditional iterative diffractive imaging methods using spatially partially coherent illumination, our method is noniterative and robust to the degradation of the spatial coherence of the illumination. In addition to diffractive imaging, the proposed method can also be applied to spatial coherence property characterization, e.g., free-space optical communication and optical coherence singularity measurement.

KW - coherent diffractive imaging

KW - noniterative method

KW - partial coherence

KW - pinhole array mask

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Noniterative spatially partially coherent diffractive imaging using pinhole array mask

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