Numerical simulation of optical propagation using sinc approximation

Cubillos, Max; Jimenez, Edwin

doi:10.1364/josaa.461355

Cited by 4 publications

(1 citation statement)

References 7 publications

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“…It influences the phase power spectral density (PSD) for the Von Karman refractive index, as described by Eq. ( 6) [42][43][44]:…”

Section: Von Karman Atmospheric Turbulence Modelmentioning

confidence: 99%

Compensation of Atmospheric Turbulence Phase Distortion Using Neural Network Adaptive Optics

Hassan

2024

IJP

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Adaptive optics revolutionizes telescopic resolution but faces cost, complexity, and calibration hurdles. Neural network adaptive optics (NNAO) offers promise by using neural networks to tailor corrections to telescopes and atmospheric conditions, by passing calibration and sensors. This MATLAB-based study examines NNAO's impact on astronomical image quality, revealing it as a cost-efficient solution that enhances adaptive optics in astronomy. The numerical simulation results were encouraging, with a compensation rate exceeding 50% due to favorable monitoring conditions. The results indicate that the dominant factor affecting image quality is the variance of wavefront aberrations. The Strehl ratio (SR) decreases from an average of 0.548 for a variance of 0.2 to 0.020 for a variance of 0.6, while the mean squared error (MSE) increases from an average of 0.613 to 5.414. However, the effect on peak signal-to-noise ratio (PSNR) is inconclusive. Furthermore, it was found that increasing the number of neurons and training ratio does not significantly impact the results obtained, but it noticeably affects the computational time required.

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“…It influences the phase power spectral density (PSD) for the Von Karman refractive index, as described by Eq. ( 6) [42][43][44]:…”

Section: Von Karman Atmospheric Turbulence Modelmentioning

confidence: 99%

Compensation of Atmospheric Turbulence Phase Distortion Using Neural Network Adaptive Optics

Hassan

2024

IJP

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Semi-analytic simulation of closed-form sources propagating through turbulence

Schmidt,

Tellez,

Gbur

2023

Unconventional Imaging, Sensing, and Adaptive Optics 2023

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This paper extends a recent fast method for simulating optical propagation through random media like atmospheric turbulence. The previously published method simulates arbitrary sources propagating through two phase screens to an observation plane using a semi-analytic technique. The new advancement in this paper covers specific cases of sources with a known, closed-form solution for the non-turbulent field as a function of propagation distance. With the closed-form expressions, the authors did additional analytic evaluation, which leaves even less numerical work for the computer. This reduces the computation further than treating the source as arbitrary. Further, this semi-analytic method has been extended to propagate the wave through a simple optical system to an image plane. The specific cases of off-axis planar and spherical waves can be used to simulate a collection of point spread functions (PSFs) that are partially correlated across the field of view. Subsequently, these PSFs can be used with an extended scene's reflectance array to synthesize an incoherent, anisoplanatic image.

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Semi-analytic simulation of optical wave propagation through turbulence

2022

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Split-step wave-optical simulations are useful for studying optical propagation through random media like atmospheric turbulence. The standard method involves alternating steps of paraxial vacuum propagation and turbulent phase accumulation. We present a semi-analytic approach to evaluating the Fresnel diffraction integral with one phase screen between the source and observation planes and another screen in the observation plane. Specifically, we express the first phase screen’s transmittance as a Fourier series, which allows us to bring phase screen effects outside of the Fresnel diffraction integral, thereby reducing the numerical computations. This particular setup is useful for simulating astronomical imaging geometries and two-screen laboratory experiments that emulate real turbulence with phase wheels, spatial light modulators, etc. Further, this is a key building block in more general semi-analytic split-step simulations that have an arbitrary number of screens. Compared with the standard angular-spectrum approach using the fast Fourier transform, the semi-analytic method provides relaxed sampling constraints and an arbitrary computational grid. Also, when a limited number of observation-plane points is evaluated or when many time steps or random draws are used, the semi-analytic method can compute faster than the angular-spectrum method.

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Numerical simulation of optical propagation using sinc approximation

Cited by 4 publications

References 7 publications

Compensation of Atmospheric Turbulence Phase Distortion Using Neural Network Adaptive Optics

Compensation of Atmospheric Turbulence Phase Distortion Using Neural Network Adaptive Optics

Semi-analytic simulation of closed-form sources propagating through turbulence

Semi-analytic simulation of optical wave propagation through turbulence

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