横向剪切干涉测量中一种获得无耦合Zernike系数的模式复原方法

孙文瀚, 王帅, 何星, 等. 横向剪切干涉测量中一种获得无耦合Zernike系数的模式复原方法[J]. 光电工程, 2019, 46(5): 180273. doi: 10.12086/oee.2019.180273
引用本文: 孙文瀚, 王帅, 何星, 等. 横向剪切干涉测量中一种获得无耦合Zernike系数的模式复原方法[J]. 光电工程, 2019, 46(5): 180273. doi: 10.12086/oee.2019.180273
Sun Wenhan, Wang Shuai, He Xing, et al. Modal wavefront reconstruction to obtain Zernike coefficient with no cross coupling in lateral shearing measurement[J]. Opto-Electronic Engineering, 2019, 46(5): 180273. doi: 10.12086/oee.2019.180273
Citation: Sun Wenhan, Wang Shuai, He Xing, et al. Modal wavefront reconstruction to obtain Zernike coefficient with no cross coupling in lateral shearing measurement[J]. Opto-Electronic Engineering, 2019, 46(5): 180273. doi: 10.12086/oee.2019.180273

横向剪切干涉测量中一种获得无耦合Zernike系数的模式复原方法

详细信息
    作者简介:
    通讯作者: 王帅(1988-),男,博士,副研究员,主要从事自适应光学的研究。E-mail:wangshuai@ioe.an.cn 许冰(1960-),男,硕士,研究员,主要从事自适应光学与激光技术的研究。E-mail:bingxu@ioe.ac.cn
  • 中图分类号: TB872

Modal wavefront reconstruction to obtain Zernike coefficient with no cross coupling in lateral shearing measurement

More Information
  • 模式耦合误差常见于横向剪切干涉测量中基于波前梯度数据的模式复原法,其原因是用于表示波前的基函数——Zernike圆多项式的导数不正交。使用一种含有Gram矩阵的矩阵方程进行复原,直接利用Zernike圆多项式m≠0模式角向导数对于权重函数w(ρ) = ρ (极坐标下)的正交性,以及Zernike圆多项式m = 0模式径向导数对于权重函数w(ρ) = ρ(1-ρ2)(极坐标下)的正交性进行复原。该方法无需构造辅助的向量函数,并可得到无耦合的Zernike系数,复原结果表明,模式耦合得到了避免。该方法可推广到环上,得到无耦合的Zernike环多项式系数。

  • Overview: Modal cross coupling frequently occurs in modal approaches from wavefront gradient data such as lateral shearing measurement through Zernike circle polynomials, since the gradients of Zernike circle polynomials are not orthogonal. We use a modal approach incorporating the Gram matrix, instead of least squares estimation, to reconstruct coefficients of modes for high sampling gradient measurement such as lateral shearing measurement. The matrix equation incorporating the Gram matrix has exactly one solution when the modes of the Gram matrix are linearly dependent. The matrix equation incorporating the Gram matrix has the solution without modal cross coupling when the modes of the Gram matrix are mutually orthogonal with respect to the same weight function of the Gram matrix. Using the orthogonality of angular derivative of m≠0 modes with respect to weight function w(ρ) = ρ (polar coordinates), one can obtain Zernike coefficients of m≠0 modes without modal cross coupling by Gram matrix method. Using the orthogonality of radial derivative of m = 0 modes with respect to weight function w(ρ) = ρ(1-ρ2) (polar coordinates), one can obtain Zernike coefficients of m≠0 modes without modal cross coupling by Gram matrix method. The Gram matrix method needs no auxiliary vector functions, and can be easily constructed and calculated. The Zernike coefficients can be obtained with no modal cross coupling. The numerical simulation results are given. Remaining error can characterize the modal cross coupling when sampling number is sufficiently high so that modal aliasing is able to be neglected. The numerical simulation result shows that the remaining error keeps very small as the truncation number J changes. The result indicates that the modal cross coupling is avoided by using Gram matrix method. This method can be easily generalized to annulus, one can obtain Zernike annular polynomial coefficients with no modal cross coupling.

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  • 图 1  波前复原误差λ和残差λr与截断数J的关系,运用本文所述式(18)与式(19)的Gram矩阵方法

    Figure 1.  Reconstruction error λ and remaining error λr versus truncation of reconstruction modes J, by Gram matrix method in Eq.(18) and Eq.(19)

    图 2  波前复原误差λ和残差λr与截断数J的关系,运用式(1) Gram矩阵方法,权重函数w(ρ) = ρ (极坐标)

    Figure 2.  Reconstruction error λ and remaining error λr versus truncation of reconstruction modes J, by Gram matrix method in Eq.(1), w(ρ) = ρ (polar coordinate)

    图 3  波前复原结果。(a)原始波前;(b)式(18)复原的m≠0项的波前;(c)式(19)复原的m = 0项的波前;(d)复原波前;(e)复原残留误差

    Figure 3.  Reconstruction results. (a) Original wavefront; (b) Reconstructed wavefront by Eq.(18), including m≠0 modes; (c) Reconstructed wavefront by Eq.(19), including m = 0 modes; (d) Reconstructed wavefront; (e) Residual error

    图 4  数值化的干涉条纹

    Figure 4.  Numerical interferogram

    图 5  波前复原结果。 运用本文所述式(19)的 Gram 矩阵方法。 (a) Zernike 离焦项 Z20 的复原波前, 截断数 J=4; (b) Zernike 离焦项 Z20 的复原波前,截断数 J=2; (c) 复原残留误差原。运用式(1)的 Gram 矩阵方法: (d) Zernike 离焦项 Z20 的复原波前,截断数 J=4; (e) Zernike 离焦项 Z20 的复原波前,截断数 J=2; (f) 复原残留误差原

    Figure 5.  Reconstruction results by Gram matrix method in Eq.(19). (a) Reconstructed wavefront of Z20 , where truncation number J=4; (b) Reconstructed wavefront of Z20 , where truncation number J=2; (c) Residual error. Reconstruction results by Gram matrix method in Eq.(1); (d) Reconstructed wavefront of Z20 , where truncation number J=4; (e) Reconstructed wavefront of Z20 , where truncation number J=2; (f) Residual error

    图 6  波前复原误差和残差λr与截断数J的关系

    Figure 6.  Reconstruction error and remaining error λr versus truncation of reconstruction modes J

    图 7  波前复原结果。 (a) 原始波前; (b) 复原波前; (c) 复原残留误差

    Figure 7.  Reconstruction results. (a) Original wavefront; (b) Reconstructed wavefront; (c) Residual error

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出版历程
收稿日期:  2018-05-23
修回日期:  2018-09-25
刊出日期:  2019-05-01

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