[1] KIPP L, SKIBOWSKI M, JOHNSON R L, et al. Sharper images by focusing soft X-rays with photon sieve［J］. Nature, 2001, 414(6860): 184-188.

[2] BAEZ A V. Fresnel zone plate for optical image formation using extreme ultraviolet and soft x radiation［J］. Journal of the Optical Society of America, 1961, 51(4): 405-412.

[3] KIRZ J. Phase zone plates for x rays and the extreme uv［J］. Journal of the Optical Society of America, 1974, 64(3): 301-309.

[4] ARSENAULT H. Diffraction theory of Fresnel zone plates［J］. Journal of the Optical Society of America, 1968, 58(11): 1536-1536.

[5] CAO Q, JAHNS J. Focusing analysis of the pinhole photon sieve: individual far-field model［J］. Journal of the Optical Society of America A, 2002, 19(12): 2387-2393.

[6] ZHANG Jun-yong, CAO Qing, LU Xing-qiang,et al. Focusing contribution of individual pinholes of a photon sieve: dependence on the order of local ring of underlying traditional Fresnel zone plate［J］. Chinese Optics Letters, 2010, 8(3): 256-258.

[7] CHENG Yi-guang, LIU Jun-bo, HU Song, et al. Generation of localized hollow beams with hoton sieves［J］. Acta Optica Sinica, 2015, 35(7): 0705003.

[8] GIMENEZ F, MONSORIU J A, FURLAN W D, et al. Fractal photon sieve［J］. Optics Express, 2006, 14(25): 11958-11963.

[9] XIE Chang-qing, ZHU Xiao-li,SHI Li-na, et al. Spiral photon sieve apodized by digital prolate spheroidal window for the generation of hard-x-ray vortex［J］. Optics Letters, 2010, 35(11): 1765-1767.

[10] ZHANG Jun-yong. Three-dimensional array diffraction-limited foci from Greek ladders to generalized Fibonacci sequences［J］. Optics Express, 2015, 23(23): 30308-30317.

[11] KINCADE K. Photon sieve enhance weapons vision［J］. Laser Focus World, 2004, 40(2): 34-37.

[12] SACCONI L, FRONER E, ANTOLINI R, et al. Multiphoton multifocal microscopy exploiting a diffractive optical element［J］.Optics Letters, 2003, 28(20): 1918-1920.

[13] LIU Yong, KUANGCui-fang, LIU Xu. A method for achieving multiple foci with subdiffraction resolution along the axial direction［J］. Journal of Modern Optics, 2015, 62(5): 364-368.

[14] MONSORIU J A, CALATAYUD A, REMON L, et al. Bifocal fibonacci diffractive lenses［J］. IEEE Photonics Journal, 2013, 5(3): 3400106.

[15] FERRANDO V, CALATAYUD A, ANDRES P, et al. Imaging properties of kinoform fibonacci lenses［J］. IEEE Photonics Journal, 2014, 6(1): 6500106.

[16] JI Sheng-zhe, ZHU Lin-wei, SUN Mei-yu, et al. Axial two focus zone plate under tight foucsing conditions［J］. Acta Optica Sinica, 2015, 35(3): 0305003.

[17] KE Jie, ZHANG Jun-yong. Focusing and imaging properties of fibonacci photon sieve［J］. Acta Optica Sinica, 2015, 35(9): 0923001.

[18] KE Jie, ZHANG Jun-yong, REN Zhi-yuan. Two approaches to three-dimensional array foci of generalized Fibonacci structures［J］. Chinese Optics Letters, 2016, 14(6): 060501.

[19] KE Jie, ZHANG Jun-yong. Focusing properties of phase-only generalized Fibonacci photon sieves［J］. Optics Communications, 2016, 368: 34-38.

[20] MACHADO F, FERRANDO V, FURLAN W D, et al. Diffractive m-bonacci lenses［J］. Optics Express, 2017, 25(7): 8267-8273.

[21] CHENG Guan-xiao, XING Ting-wen, YANG Yong, et al. Experimental characterization of optical properties of photon sieve［C］. SPIE, 2007, 6724(535): 67240D.

[22] GAO Zhong, LUO Xian-gang, MA Jun-xian,et al. Imaging properties of photon sieve with a large aperture［J］. Optics & Laser Technology, 2008, 40(4): 614-618.

[23] SCHNARS U, JUPTNER W. Direct recording of holograms by a CCD target and numerical reconstruction［J］. Applied Optics, 1994, 33(2): 179-181.

[24] YAMAGUCHI I. Phase-shifting digital holography［J］. Optics Letters, 1997, 22(16): 1268-1270.

[25] CUCHE E, BEVILACQUA F, DEPEURSINGE C. Digital holography for quantitative phase-contrast imaging［J］. Optics Letters, 1999, 24(5): 291-293.

[26] WENGJia-wen, YANG Chu-ping, LI Hai. Self-interference incoherent digital holography by compressive sensing［J］. Acta Optica Sinica, 2016, 36(2): 0209001.

[27] HUANG Su-juan, ZENG Jun-zhang, YAN Cheng, et al. 3D Refractive index measurement for spun polarization-maintaining optical fiber［J］. Acta Photonica Sinica, 2017, 46(6): 0612001.

[28] PANDIYAN VP, KHARE K, JOHN R. High resolution near on-axis digital holography using constrained optimization approach with faster convergence［J］. Optical Engineering, 2017, 56(9): 093103.

[29] WANG Jun, YANG Rong, ZHENG Jiao, et al. Visualized measurement of the liquid phase difusion by using digital holographic interferometry［J］. Acta Photonica Sinica, 2016, 45(4): 0412001.

[30] XU Y, TAN B S, LAW G H, et al. A digital holography microscopy system for DOE measurement［C］. SPIE, 2017, 10449: 1044903.

[31] OSLER T J, WRIGHT M, ORCHARD M. Theon′s ladder for any root［J］. International Journal of Mathematical Education in Science & Technology, 2005, 36(4): 389-398.

[32] FERRARO P, NICOLA S D, FINIZIO A, et al. Compensation of the inherent wave front curvature in digital holographic coherent microscopy for quantitative phase-contrast imaging［J］. Applied Optics, 2003, 42(11): 1938-1946.

[33] FEIGENBAUM E, SACKS R A, MCCANDLESS K P, et al. Algorithm for Fourier propagation through the near-focal region［J］. Applied Optics, 2013, 52(20): 5030-5035.

[34] QU Wei-juan. Domain structure detection in crystal by use of digital holographic interferometry and aperture diffraction calculation［D］. Shanghai institute of optics and fine mechanics, Chinese academy of sciences, 2007: 19-40.

[35] LI Wei-liang. Research on autofocusing and image enhancement technology in digital holography［D］. Nanjing: Nanjing university of posts and telecommunications, 2016: 24-32.

[36] MEMMOLO P, DISTANTE C, PATURZO M, et al. Automatic focusing in digital holography and its application to stretched holograms［J］. Optics Letters, 2011, 36(10): 1945-1947.

[37] ILHAN H A, DOGAR M, OZCAN M. Fast autofocusing in digital holography using scaled hologram［J］. Optics Communications, 2013, 287(2): 81-84.