[1] BOHN S, SPERLICH K, STAHNKE T et al. Multiwavelength confocal laser scanning microscopy of the cornea[J]. Optics Express, 11, 5689-5700(2020).

[2] LU W L, CHEN C, WANG J et al. Characterization of the displacement response in chromatic confocal microscopy with a hybrid radial basis function network[J]. Optics Express, 27, 22737-22752(2019).

[3] LI J F, ZHAO Y L, DU H et al. Adaptive modal decomposition based overlapping-peaks extraction for thickness measurement in chromatic confocal microscopy[J]. Optics Express, 28, 36176-36187(2020).

[4] LUO J, ZHANG H D, ERIK F et al. Confocal hyperspectral microscopic imager for the detection and classification of individual microalgae[J]. Optics Express, 29, 37281-37301(2021).

[5] SHAO Tanbin, GUO Wenping, XI Yinghao et al. Design and performance evaluation of chromatic confocal displacement sensor with high measuring range[J]. Chinese Journal of Lasers, 49, 62-69(2022).

[6] CUI Changcai, LI Huang, YU Qing et al. Design of adjustable dispersive objective lens for chromatic confocal system[J]. Optics and Precision Engineering, 25, 343-351(2017).

[7] YAO J N, THOMPSON K P, MA B et al. Volumetric rendering and metrology of spherical gradient refractive index lens imaged by angular scan optical coherence tomography system[J]. Optics Express, 24, 19388-19404(2016).

[8] SUN Jianmei, CHEN Feilu, YANG Chenye et al. F-P interferometer vibration measurement experimental system based on ultra-small grin fiber probe[J]. Optics and Precision Engineering, 29, 1518-1526(2021).

[9] CONOR J S, ALEXANDER V G. Accommodating volume-constant age-dependent optical (AVOCADO) model of the crystalline GRIN lens[J]. Biomedical Optics Express, 7, 1985-1999(2016).

[10] JOHN A E, SAWYER D C, JOGENDER N et al. Analytical surrogate model for the aberrations of an arbitrary GRIN lens[J]. Optics Express, 24, 17805-17818(2016).

[11] SARAH L, SUN P C, FAIN Y. Diffractive lenses for chromatic confocal imaging[J]. Applied Optics, 36, 4744-4748(1997).

[12] LIU Q, YANG W C, WANG Y. Design of linear dispersive objective for chromatic confocal microscope[J]. Optical Engineering, 21, 2473-2475(2013).

[13] MA J, QI Y J, GUANG Y. Design of linear dispersive objective for chromatic confocal displacement sensor[J]. Chinese Journal of Lasers, 46, 219-225(2019).

[14] LI Chunyan, LI Gengpeng, LIU Jihong et al. Thickness measurement of radial GRIN lens under eccentricity by spectral confocal method[J]. Optics and Precision Engineering, 30, 2067-2076(2022).

[15] LI Chunyan, LI Gengpeng, LIU Jihong et al. Analysis and research on spectral confocal displacement measurement method based on GRNN[J]. Acta Photonica Sinica, 51, 0330001(2022).

[16] LI C Y, LI G P, LIU J H et al. Influence of eccentricity and tilt of radial GRIN lens on its thickness measurement by chromatic confocal technology[J]. Optical Engineering, 60, 094107(2021).

[17] LI C Y, LI K, LIU J H et al. Design of a confocal dispersion objective lens based on the GRIN lens[J]. Optics Express, 30, 44290-44299(2022).

[18] MATTHEW C, MARIAN H, PAUL K et al. The development and investigation of displacement sensor[J]. Metrology & Measurement Technique, 85, 714-720(2009).

[19] RUBIN N A, SHI Z J, FEDERICO C. Polarization in diffractive optics and metasurfaces[J]. Advances in Optics and Photonics, 13, 836-970(2021).

[21] PAN S Y, WANG S Q, XU J H et al. Sub-pixel position estimation algorithm based on Gaussian fitting and sampling theorem interpolation for wafer alignment[J]. Applied Optics, 60, 9607-9618(2021).

[22] LEE H W, PARK H J, LEE J H et al. Accuracy improvement in peak positioning of spectrally distorted fiber Bragg grating sensors by Gaussian curve fitting[J]. Applied Optics, 46, 2205-2208(2007).

[23] ZHAO C Y, JAMES H. Orthonormal curvature polynomials over a unit circle: basis set derived from curvatures of Zernike polynomials[J]. Optics Express, 21, 31430-31442(2013).

[24] HAO Mengfan. Research on three dimensional measurement system based on spining disk confocal microscopy[D](2022).