Li Ziqiang, Li Xinyang
Opt Express. 2018 Nov 26;26(24):31675-31692. doi: 10.1364/OE.26.031675.
This paper proposes a method used to calculate centroid for Shack-Hartmann wavefront sensor (SHWFS) in adaptive optics (AO) systems that suffer from strong environmental light and noise pollutions. In these extreme situations, traditional centroid calculation methods are invalid. The proposed method is based on the artificial neural networks that are designed for SHWFS, which is named SHWFS-Neural Network (SHNN). By transforming spot detection problem into a classification problem, SHNNs first find out the spot center, and then calculate centroid. In extreme low signal-noise ratio (SNR) situations with peak SNR (SNR) of 3, False Rate of SHNN-50 (SHNN with 50 hidden layer neurons) is 6%, and that of SHNN-900 (SHNN with 900 hidden layer neurons) is 0%, while traditional methods' best result is 26 percent. With the increase of environmental light interference's power, the False Rate of SHNN-900 remains around 0%, while traditional methods' performance decreases dramatically. In addition, experiment results of the wavefront reconstruction are presented. The proposed SHNNs achieve significantly improved performance, compared with the traditional method, the Root Mean Square (RMS) of residual decreases from 0.5349 um to 0.0383 um. This method can improve SHWFS's robustness.
本文提出了一种用于在遭受强环境光和噪声污染的自适应光学(AO)系统中计算夏克-哈特曼波前传感器(SHWFS)质心的方法。在这些极端情况下,传统的质心计算方法无效。所提出的方法基于为SHWFS设计的人工神经网络,称为SHWFS神经网络(SHNN)。通过将光斑检测问题转化为分类问题,SHNN首先找出光斑中心,然后计算质心。在峰值信噪比(SNR)为3的极低信噪比(SNR)情况下,SHNN-50(具有50个隐藏层神经元的SHNN)的误识率为6%,而SHNN-900(具有900个隐藏层神经元的SHNN)的误识率为0%,而传统方法的最佳结果为26%。随着环境光干扰功率的增加,SHNN-900的误识率保持在0%左右,而传统方法的性能则显著下降。此外,还给出了波前重建的实验结果。与传统方法相比,所提出的SHNN性能显著提高,残余均方根(RMS)从0.5349μm降至0.0383μm。该方法可以提高SHWFS的鲁棒性。
