Speckle-Correlation Scattering Matrix Approaches for Imaging and Sensing through Turbidity

Baek, YoonSeok; Lee, KyeoReh; Oh, Jeong-hun; Park, YongKeun

doi:10.3390/s20113147

Cited by 11 publications

(7 citation statements)

References 102 publications

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“…From the measured speckle pattern, the SSM method is applied using the designed TM. [ 9,10 ] To describe the reconstruction sequence, let us consider the orthonormal basis of the input field,

U = \{{\bf{e}}_1,{\bf{e}}_2,\ldots,{\bf{e}}_N\}

. The basis can freely be defined such that it satisfies

{\bf{x}} = \sum\nolimits_{i = 1}^N {{x_i}{{\bf{e}}_i}}

, where

{\bf x}\in {\mathbb C}^{N}

is an unknown input field.…”

Section: Resultsmentioning

confidence: 99%

“…[ 3 ] To address this, various reference‐free holographic imaging techniques have been developed. [ 4–9 ] Because phase is not a directly measurable quantity, most reference‐free phase imaging methods must either make a priori constraints on an input field or conduct multiple measurements. For example, coherent diffractive imaging utilizes sample support, [ 4 ] integration methods assume a well‐defined phase (no dark points) over the entire field of view, [ 5 ] and the transport of intensity equation methods [ 6 ] and ptychography exploit axial and lateral sample scanning to increase the number of sampling points.…”

Section: Introductionmentioning

confidence: 99%

“…The constraint‐free feature is derived from the reconstruction algorithm, which only utilizes the given transmission matrix (TM) of the used diffuser and the mathematical relation between the diffused speckle fields. [ 9,10 ]…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Single‐Shot Reference‐Free Holographic Imaging using a Liquid Crystal Geometric Phase Diffuser

Lee

Park

2021

Laser & Photonics Reviews

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It has been recently demonstrated that wavefront information can be directly measured using the speckle‐correlation scattering method. The realization of speckle‐correlation scattering requires the use of a diffusive layer; however, it poses technical challenges in characterizing the transmission matrix of the diffusive layer or precisely fabricating an engineered random metasurface. Herein, liquid crystal geometric phase diffusers are exploited for single‐shot reference‐free holographic imaging based on speckle‐correlation scattering. It is demonstrated that the use of a commercial geometric phase diffuser provides precise holographic measurements in a simple imaging setup, with no calibration required. This low‐cost, simple, and high‐resolution wavefront sensing approach inspired by liquid crystal materials may find direct applications in metrology, industrial inspection, and biophotonics.

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“…From the measured speckle pattern, the SSM method is applied using the designed TM. [ 9,10 ] To describe the reconstruction sequence, let us consider the orthonormal basis of the input field,

U = \{{\bf{e}}_1,{\bf{e}}_2,\ldots,{\bf{e}}_N\}

. The basis can freely be defined such that it satisfies

{\bf{x}} = \sum\nolimits_{i = 1}^N {{x_i}{{\bf{e}}_i}}

, where

{\bf x}\in {\mathbb C}^{N}

is an unknown input field.…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Single‐Shot Reference‐Free Holographic Imaging using a Liquid Crystal Geometric Phase Diffuser

Lee

Park

2021

Laser & Photonics Reviews

Self Cite

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“…In CSI, we transform the sample field into a random speckle before the measurement using an X-ray diffuser 36 . Although the phase of the speckle is immeasurable either, the complex-valued sample field can be uniquely reconstructed from the magnitude image through the pseudorandomness of speckle [37][38][39][40] . Our CSI exploits a designed X-ray diffuser after the sample instead of a zone plate (Fig.…”

Section: Introductionmentioning

confidence: 99%

Direct high-resolution X-ray imaging exploiting pseudorandomness

et al. 2023

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Owing to its unique penetrating power and high-resolution capability, X-ray imaging has been an irreplaceable tool since its discovery. Despite the significance, the resolution of X-ray imaging has largely been limited by the technical difficulties on X-ray lens making. Various lensless imaging methods have been proposed, but are yet relying on multiple measurements or additional constraints on measurements or samples. Here we present coherent speckle-correlation imaging (CSI) using a designed X-ray diffuser. CSI has no prerequisites for samples or measurements. Instead, from a single shot measurement, the complex sample field is retrieved based on the pseudorandomness of the speckle intensity pattern, ensured through a diffuser. We achieve a spatial resolution of 13.9 nm at 5.46 keV, beating the feature size of the diffuser used (300 nm). The high-resolution imaging capability is theoretically explained based on fundamental and practical limits. We expect the CSI to be a versatile tool for navigating the unexplored world of nanometer.

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“…This method requires auxiliary equipment in most cases, which limits its application in practice. Speckle correlation imaging [10][11][12] based on the "memory effect" [13] of the scattering medium has also attracted research interest. The experimental requirements of speckle-related methods are relatively simple, but the imaging field of view is limited by the memory effect range, which is inversely proportional to the medium thickness.…”

Section: Introductionmentioning

confidence: 99%

Improving Compressed Sensing Image Reconstruction Based on Atmospheric Modulation Using the Distributed Cumulative Synthesis Method

Lei

Yang

et al. 2021

IEEE Photonics J.

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The problem of long-distance imaging through timevarying scattering media, such as the atmosphere, is encountered in many science fields. Recent studies have demonstrated that random atmospheric variability can be considered a spatial light modulator in compressed sensing imaging. However, the quality of the reconstructed image needs to be further improved. In this paper, we propose a distributed cumulative synthesis method to improve the compressed sensing image reconstruction based on atmospheric modulation. For multiple original images of various types, the compressed sensing imaging simulation experiment with different sampling rates was conducted using the distributed cumulative synthesis method. The simulation results show that, compared with the imaging method using a single light source, the distributed cumulative synthesis method can effectively improve the quality of the reconstructed image, whether it is full sampling or undersampling. In addition, a sparsity impact factor is defined to quantify the reconstruction ability of the measurement matrix obtained by the distributed cumulative synthesis method. This value can be used as an evaluation index for the optimized design of the measurement matrix by the distributed cumulative synthesis method. Noise analysis shows that the proposed method has better anti-noise performance than the single light source imaging method.

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Speckle-Correlation Scattering Matrix Approaches for Imaging and Sensing through Turbidity

Cited by 11 publications

References 102 publications

Single‐Shot Reference‐Free Holographic Imaging using a Liquid Crystal Geometric Phase Diffuser

Single‐Shot Reference‐Free Holographic Imaging using a Liquid Crystal Geometric Phase Diffuser

Direct high-resolution X-ray imaging exploiting pseudorandomness

Improving Compressed Sensing Image Reconstruction Based on Atmospheric Modulation Using the Distributed Cumulative Synthesis Method

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