Numerical Simulation of Neural Network Based on Adaptive Optics for Correcting Phase Distortion in Astronomical Observations

Iraqi Journal of Physics Pub Date : 2024-03-01 DOI:10.30723/ijp.v22i1.1203

Raaid Nawfee Hassan

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Abstract

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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基于自适应光学的神经网络在天文观测中校正相位失真的数值模拟

自适应光学技术彻底改变了望远镜的分辨率，但也面临着成本、复杂性和校准方面的障碍。神经网络自适应光学（NNAO）通过校准和传感器，利用神经网络对望远镜和大气条件进行定制校正，从而带来了希望。这项基于 MATLAB 的研究探讨了 NNAO 对天文图像质量的影响，揭示了它是一种可增强天文学自适应光学的经济高效的解决方案。数值模拟结果令人鼓舞，由于监测条件良好，补偿率超过了 50%。结果表明，影响图像质量的主要因素是波前像差的方差。斯特雷尔比（SR）从方差为 0.2 时的平均 0.548 下降到方差为 0.6 时的 0.020，而均方误差（MSE）则从平均 0.613 增加到 5.414。然而，对峰值信噪比（PSNR）的影响并不确定。此外，研究还发现，增加神经元数量和训练比率不会对所获得的结果产生显著影响，但会明显影响所需的计算时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Iraqi Journal of Physics

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