Sparse scanning Hartmann wavefront sensor

被引：1

作者：

Xu H. ^{[1
]}

Wu J. ^{[1
]}

机构：

[1] Biophotonics Laboratory, University of Michigan – Shanghai Jiao Tong University Joint Institute, Shanghai Jiao Tong University, 800 Dongchuan Road, Shanghai, Minhang District

来源：

Optics Communications | 2023年 / 530卷

基金：

中国国家自然科学基金;

关键词：

Compressed sensing; Dynamic range; Extended aperture; Optical measurement; Spatial resolution; Wavefront reconstruction;

D O I：

10.1016/j.optcom.2022.129148

中图分类号：

学科分类号：

摘要：

We propose a sparse scanning Hartmann wavefront sensor (SS-HWFS), which decouples the dynamic range and spatial resolution that used to be traded off in a conventional HWFS by removing its arrayed architecture. In addition, the SS-HWFS applies the compressed sensing (CS) reconstruction and is able to restore the wavefront with a sparsely-chosen acquisition. In the SS-HWFS, a collimated beam as the reference is incident on the sample, which is then sparsely scanned over by a pinhole. The wavefront slopes are measured by tracking the diffraction spots recorded by an imaging sensor behind the pinhole. The wavefront is then reconstructed by assuming sparsity in the Zernike domain, which is frequently used for aberration analysis. Compared with traditional Hartmann wavefront sensors (HWFS), the SS-HWFS could achieve high spatial resolution, extensive dynamic range, extended aperture, and compressed acquisition simultaneously, which is a great benefit for the non-null testing of static optical components. Our sparse scanning wavefront measurement scheme is applicable not only for the HWFS but also for the Shack–Hartmann wavefront sensor (SHWFS). Wavefront measurement of a free-form lens is performed to demonstrate the capability of our proposed method. © 2022 Elsevier B.V.

引用

共 34 条

[11] Fang F.Z., Zhang X.D., Weckenmann A., Zhang G.X., Evans C., Manufacturing and measurement of freeform optics, CIRP Ann. - Manuf. Technol., 62, 2, pp. 823-846, (2013)
[12] Forbes G.W., Characterizing the shape of freeform optics, Opt. Express, 20, 3, pp. 2483-2499, (2012)
[13] Xue S., Chen S., Fan Z., Zhai D., Adaptive wavefront interferometry for unknown free-form surfaces, Opt. Express, 26, 17, pp. 21910-21928, (2018)
[14] Thibos L.N., From wavefronts to refractions, Adaptive Optics for Vision Science, pp. 331-362, (2006)
[15] Chaudhuri R., Papa J., Rolland J.P., System design of a single-shot reconfigurable null test using a spatial light modulator for freeform metrology, Opt. Lett., 44, 8, pp. 2000-2003, (2019)
[16] Baer G., Schindler J., Pruss C., Siepmann J., Osten W., Fast and flexible non-null testing of aspheres and free-form surfaces with the tilted-wave-interferometer, Int. J. Optomech., 8, 4, pp. 242-250, (2014)
[17] Sykora D.M., Groot P.D., Instantaneous measurement Fizeau interferometer with high spatial resolution, (2012)
[18] Stuerwald S., Error compensation in computer generated hologram-based form testing of aspheres, Appl. Opt., 53, 35, pp. 8249-8255, (2014)
[19] Southwell W.H., Wave-front estimation from wave-front slope measurements, J. Opt. Soc. Am, 70, 8, pp. 998-1006, (1980)
[20] Xu H., Wu J., Extended aperture line-scanning hartmann wavefront sensor, Appl. Opt., 60, 12, pp. 3403-3411, (2021)

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