光学 精密工程, 2018, 26 (4): 771, 网络出版: 2018-08-28
采用单位激励影响矩阵数值计算的瑞奇-康芒检测技术
Ritchey-Common interferometry using unit-excitation influence matrix’s numerical calculation method
光学检测 单位激励法 数值计算 瑞奇-康芒法 Zernike拟合 optical inspection unit-excitation method numerical calculation Ritchey-Common method Zernike fitting
摘要
在影响矩阵法瑞奇-康芒检验中, 恢复被测面形的关键在于构建被检平面面形误差与系统波像差之间的Zernike系数影响矩阵。为了提高瑞奇-康芒法的检测精度, 研究了采用单位激励法来精确计算影响矩阵的方法。分别重构平面镜仅包含某一种Zernike波像差下的系统波像差分布, 经Zernike拟合得到该种Zernike像差的影响系数向量; 由各Zernike像差的影响系数向量组成影响矩阵, 然后用最小二乘拟合出被检平面面形。对口径为90 mm的平面镜进行实际检验, 在瑞奇角为26.5°与40.6°的情况下进行波前恢复, 得到被检平面镜PV值为0.141 3λ, RMS为0.019 4λ。与直接采用平面参考镜检测相比, 瑞奇-康芒法检测误差PV值为0.082 8λ, RMS为0.010 9λ。该方法能够精确生成影响矩阵, 抑制了影响矩阵法中对大F数的依赖, 可用于精确恢复平面镜面形。
Abstract
Calculating the influence matrix between surface error and wavefront aberration is a key step in the Ritchey-Common test. A method that uses unit-excitation operation to calculate the influence matrix with high accuracy was studied in order to improve the precision of the test. It retrieves the system wavefront aberration when the flat mirror concludes only one kind of Zernike aberration, and obtains the influence coefficient vector through Zernike fitting. The influence matrix is formed from the coefficient vectors of all the Zernike aberrations. Least square fitting is then used to reconstruct the surface shape of the tested mirror. After reconstructing the wavefront with Ritchey angles of 26.5° and 40.5°, the test results show PV and RMS values of 0.1413λ and 0.0194λ respectively for the Φ90 mm flat mirror. Compared to the results from direct testing, the PV and RMS error in the Ritchey-Common method are 0.0828λ and 0.0109λ, respectively. This method can calculate the influence matrix accurately, eliminate the dependence on the big F-number in traditional influence matrix methods and can reconstruct the surface shape with high precision.
刘一鸣, 李金鹏, 陈磊, 林冬冬, 郑锋华. 采用单位激励影响矩阵数值计算的瑞奇-康芒检测技术[J]. 光学 精密工程, 2018, 26(4): 771. LIU Yi-ming, LI Jin-peng, CHEN Lei, LIN Dong-dong, ZHENG Feng-hua. Ritchey-Common interferometry using unit-excitation influence matrix’s numerical calculation method[J]. Optics and Precision Engineering, 2018, 26(4): 771.