Coherence entropy during propagation through complex media

Lu, Xingyuan; Wang, Zhuoyi; Zhan, Qiwen; Cai, Yangjian; Zhao, Chengliang

doi:10.1117/1.ap.6.4.046002

Adv. Photon.

2024

DOI: 10.1117/1.ap.6.4.046002

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Coherence entropy during propagation through complex media

Xingyuan Lu,

Zhuoyi Wang,

Qiwen Zhan

et al.

Abstract: The deformation, flicker, and drift of a light field owing to complex media such as a turbulent atmosphere have limited its practical applications. Thus, research on invariants in randomly fluctuated light fields has garnered considerable attention in recent years. Coherence is a statistical property of light, while its full and quantitative characterization is challenging. Herein, we successfully realize the orthogonal modal decomposition of partially coherent beams and introduce the application of coherence … Show more

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Cited by 5 publications

References 46 publications

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Overlap-scanning self-referencing diffractive imaging with enlarged field of view under incoherent illumination

Sun,

Wang,

Ouyang

et al. 2025

Applied Physics Letters

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Coherent diffractive imaging (CDI), especially the ptychography, has been widely used in quantitative phase imaging. However, in traditional diffractive imaging schemes, a highly coherent light source is required for a better-posed inverse problem. Considering that the high coherence cannot be guaranteed in all cases and to avoid the multi-mode of low-coherence light sources complicating the iterative modeling of diffractive imaging, we proposed an overlap-scanning self-referencing diffractive imaging. As a non-iterative partially coherent diffractive imaging method, self-referencing diffractive imaging was combined with the procedure of overlap-scanning ptychography. It does not require prior knowledge of light source coherence, and only a coherent inverse problem was needed to be solved in the final stitching. It has been demonstrated to be able to recover the complex amplitude of objects illuminated by various low-coherence light sources. This study presents significant potential for applications in phase imaging with a wide-field of view under incoherent illuminations.

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Overlap-scanning self-referencing diffractive imaging with enlarged field of view under incoherent illumination

Sun,

Wang,

Ouyang

et al. 2025

Applied Physics Letters

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Twisted complex-variable-function Gaussian model beams with special correlations

Zhou,

Wei,

Zhang

et al. 2024

Phys. Scr.

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We introduce a new class of twisted complex-variable-function Gaussian model (TCVFGM) beams and provide the propagating cross-spectral density (CSD) of optical beams with various correlations. Sufficient conditions are provided to guarantee that the CSD function is physically genuine. We designed an experimental setup to synthesize TCVFGM beams endowed with various correlations using complex transmittance screens. The experimental results of a sinc-correlated TCVFGM source are presented, indicating that the spectral density is present as an array and rotates during propagation. These findings may be useful in beam shaping and particle manipulation.

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Twisted hyperbolic-sine-correlated beams

Xu,

Wang,

Peng

et al. 2024

Opt. Express

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In this study, a novel class of spatially non-uniformly correlated beams called twisted hyperbolic-sine-correlated (THSC) beams is introduced. The coherence structure of such beam sources is characterized by a hyperbolic sine function with a high-order twist phase embedded in its argument. The propagation properties of the THSC beams are numerically examined in detail. Our results reveal that the order numbers and twist factor of the twist phase has a significant effect on the spectral density and orbital angular momentum (OAM) flux density upon propagation, and they can be used to control the formation of certain specific far-field intensity profiles such as doughnut shape, rectangular window shape, and dumbbell-like shape, as well as the OAM flux distributions such as windmill-like shape. In addition, the THSC beams under certain order numbers may possess peculiar propagation characteristics such as diffraction-effect suppression, lateral shift of intensity maxima and beam spot rotation. Further, we have established a flexible yet compact experimental system to synthesize such kind of beam sources. The evolution properties of the intensity distribution are investigated and analyzed in the experiment.

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Coherence entropy during propagation through complex media

Cited by 5 publications

References 46 publications

Overlap-scanning self-referencing diffractive imaging with enlarged field of view under incoherent illumination

Overlap-scanning self-referencing diffractive imaging with enlarged field of view under incoherent illumination

Twisted complex-variable-function Gaussian model beams with special correlations

Twisted hyperbolic-sine-correlated beams

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