5 April 2000 Analysis of primary aberration with the two-dimension discrete wavelet transform
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Abstract
As is known, Zernike polynomials find broad application for the solution of many problems of computational optics. The well-known Zernike polynomials are particularly attractive for their unique properties over a circular aperture. Zernike circle polynomials are used for describing both classical aberrations in optical system and aberrations related to atmospheric turbulence. There are several numerical techniques to solve for the value of Zernike coefficients, the least-squares matrix inversion method and the Gram-Schmidt orthogonalization method would become ill- conditioned due to an improper data sampling. In this article, we present the 2D discrete wavelet transform (DWT) technique to find the 3rd order spherical and coma aberration coefficients. The method offers great improvement in the accuracy and calculating speed of the fitting aberration coefficients better than the least-squares matrix inversion method and the Gram-Schmidt orthogonalization method. Furthermore, the result of solving coefficients through the 2D DWT is independent of the order of the polynomial expansion. So we can find an accurate value from the datum of fitting.
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Jin-Yi Sheu, Rang-Seng Chang, Ching-Huang Lin, "Analysis of primary aberration with the two-dimension discrete wavelet transform", Proc. SPIE 4056, Wavelet Applications VII, (5 April 2000); doi: 10.1117/12.381698; https://doi.org/10.1117/12.381698
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