Wavefront reconstruction method based on far-field information and convolutional neural network

Q4 Engineering
Shi Zongjia, Xiang Zhenjiao, Du Yinglei, Wan Min, gu jing-liang, Li Guohui, Xiang Rujian, You Jiang, Wu Jing, Xu Honglai
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引用次数: 1

Abstract

Detecting wavefront phase information is the key to realize adaptive optics wavefront compensation. Using convolutional neural network (CNN) instead of wavefront sensor for wavefront reconstruction, the system can be simple and easy to implement, and the reconstruction process is fast and real-time without iteration. To extract the wavefront features from the far field accurately, CNN needs to use a large number of samples for training in advance. In the study, according to the corresponding relationship between Zernike aberration coefficient of orders 4 to 30 and its far-field intensity, the sample data set was simulated, CNN was trained to predict the Zernike aberration coefficient of the distorted wavefront from an input far-field image, then reconstruct the original wavefront. The experimental results show that this method can restore the phase information of wavefront quickly and in real time. Compared with the original wavefront, the reconstructed wavefront has higher wavefront coincidence and smaller residual. It is expected to realize the closed-loop correction in practical adaptive optics systems.
基于远场信息和卷积神经网络的波前重构方法
波前相位信息的检测是实现自适应光学波前补偿的关键。利用卷积神经网络(CNN)代替波前传感器进行波前重建,系统简单易行,重建过程快速实时,无需迭代。为了准确提取远场的波前特征,CNN需要事先使用大量的样本进行训练。在本研究中,根据4 ~ 30阶泽尼克像差系数与其远场强度的对应关系,对样本数据集进行模拟,训练CNN从输入的远场图像中预测畸变波前的泽尼克像差系数,然后重建原波前。实验结果表明,该方法可以快速实时地恢复波前的相位信息。与原始波前相比,重构波前具有更高的波前吻合度和更小的残差。期望在实际的自适应光学系统中实现闭环校正。
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来源期刊
强激光与粒子束
强激光与粒子束 Engineering-Electrical and Electronic Engineering
CiteScore
0.90
自引率
0.00%
发文量
11289
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