光学 精密工程, 2014, 22 (12): 3175, 网络出版: 2015-01-13   

相位差异法检测不理想环境下的非共光路像差

Calibration of no-common path aberration using multi-channel phase-diversity wave-front sensing
作者单位
中国科学院 长春光学精密机械与物理研究所, 吉林 长春 130033
摘要
设计了1.23 m地基望远镜自适应系统的非共光路标定系统。针对自适应光学系统非共光路像差检测中遇到的问题, 构造了离焦量不可测情况下的相位差异法的评价函数。利用多通道约束波前的解集和像差检测与变形镜调整互相迭代最终收敛的办法, 弥补了测量条件不理想对像差检测的影响。与双通道相位差异法相比, 多通道相位差异法对目标光源形状的容忍力更强, 理论上对波前求解精度更高。将该方法应用于1.23 m地基望远镜自适应系统的非共光路静态像差测量中, 取得了良好的效果, 使光路装调更加方便。通过改变变形镜的初始偏置对测得的像差进行校正, 提高了望远镜光学系统的成像质量。
Abstract
A no-common path calibration system was desighned for the Adaptive Optical (AO) system in a 1.23 m ground telescope. To solve some practical problems of no-common path static aberration calibration, the evaluation function for the multi-channel Phase Diversity (PD) processing method was presented for a condition of the defocusinng amount difficult to be measured. Then, a method to use the detected aberration and the modulated deformable mirror to iterate each other for convergence was proposed to make up the effect of nonideal measurement conditions on aberration detection. As compared with two-channel PD processing, the multi-channel PD processing method has stronger tolerance to the forms of target sources and higher accuracy of wavefront solution in theory . The processing method was used to measure the no-common path aberration of the AO system in the 1.23 m telescope. Experimental results demonstrate that the proposed method achieves the higher accuracy of wavefront solution and the aberration has been compensated by using the initial bias of a deformable mirror.Moreover, the whole imaging quality of the optical system is improved effectively.

马鑫雪, 王斌, 李正炜. 相位差异法检测不理想环境下的非共光路像差[J]. 光学 精密工程, 2014, 22(12): 3175. MA Xin-xue, WANG Bin, LI Zheng-wei. Calibration of no-common path aberration using multi-channel phase-diversity wave-front sensing[J]. Optics and Precision Engineering, 2014, 22(12): 3175.

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