[1] [1] Gabor Dennis. A new microscopic principle[J]. Nature，1948，161 (4098)：777-778.

[2] [2] Meng Hui, Pan Gang, Pu Ye, et al.. Holographic particle image velocimetry: from film to digital recording[J]. Meas Sci & Technol，2004，15 (4)：673-685.

[3] [3] Vikram C S, Thompson BJ. Particle Field Holography[M]. Cambridge: Cambridge University Press, 2005.

[4] [4] Schnars Ulf, Jueptner Werner. Digital Holography: Digital Hologram Recording, Numerical Reconstruction, and Related Techniques[M]. Springer, 2005.

[5] [5] Cai Xiaoshu, Su Mingxiu, Shen Jiangqi. Particle Size Measurement Techniques and Application[M]. Beijing: Chemical Industry Press, 2010.

[6] [6] Pu S L, Allano D, Patte-Rouland B, et al.. Particle field characterization by digital in-line holography: 3D location and sizing[J]. Exp Fluids，2005，39 (1)：1-9.

[7] [7] Hinsch K D. Holographic particle image velocimetry[J]. Meas Sci & Technol，2002，13(7): R61-R72.

[8] [8] Satake Shin-Ichi, Kunugi Tomoaki, Sato Kazuho, et al.. Digital holographic particle tracking velocimetry for 3-D transient flow around an obstacle in a narrow channel[J]. Opt Rev，2004，11 (3)：162-164.

[9] [9] Cheong Fook Chiong, Krishnatreya Bhaskar Jyoti, Grier David G. Strategies for three-dimensional particle tracking with holographic video microscopy[J]. Opt Express，2010，18 (13)： 13563-13573.

[10] [10] Orlov S S, Abarzhi S I, Oh S B, et al.. High-performance holographic technologies for fluid-dynamics experiments[J]. Phil Trans R Soc A: Mathematical, Physical and Engineering Sciences，2010，368 (1916)：1705-1737.

[11] [11] Choo Yeon-Jun, Kang Bo-Seon. Measurements of three-dimensional velocities of spray droplets using the holographic velocimetry system[J]. KSME International J，2003，17 (7)：1095-1103.

[12] [12] Müller J, Kebbel V, Jüptner W. Characterization of spatial particle distributions in a spray-forming process using digital holography[J]. Meas Sci & Technol，2004，15(4): 706-710.

[13] [13] Lü Qieni, Chen Yiliang, Yuan Rui, et al.. Trajectory and velocity measurement of a particle in spray by digital holography[J]. Appl Opt， 2009，48(36)：7000-7007.

[14] [14] Yang Y, Kang B. Digital particle holographic system for measurements of spray field characteristics[J]. Opt & Lasers in Eng，2011，49 (11)： 1254-1263.

[15] [15] Konrath, Konrath R, Schrder, et al.. Holographic particle image velocimetry applied to the flow within the cylinder of a four-valve internal combustion engine[J]. Exp Fluids，2002，33 (6)：781-793.

[16] [16] Wu Yingchun, Wu Xuecheng, Zhou Binwu, et al.. Coal particle measurement of pulverized coal flame with digital inline holography, in digital holography and 3D imaging[C]. OSA. Kohala Coast, Hawaii United States, 2013. DW3A.3.

[17] [17] Katz J, Sheng J. Applications of holography in fluid mechanics and particle dynamics[J]. Annual Review of Fluid Mechanics，2010，42: 531-555.

[18] [18] Gouesbet Gêrard, Gréhan Gérard. Generalized Lorenz-Mie Theories[M]. Springer, 2011.

[19] [19] Yuan Y J, Ren K F, Coetmellec S, et al.. Rigorous description of holograms of particles illuminated by an astigmatic elliptical Gaussian beam[C]. J Phys Conf Ser, 2009, 147(1): 012052.

[20] [20] Wu Yingchun, Wu Xuecheng, Saengkaew Sawitree, et al.. Digital Gabor and off-axis particle holography by shaped beams: a numerical investigation with GLMT[J]. Opt Commun， 2013，305： 247-254.

[21] [21] Pu Y, Meng H. Intrinsic aberrations due to Mie scattering in particle holography[J]. J Opt Soc Am A， 2003，20 (10)：1920-1932.

[22] [22] Wu Xuecheng, Meunier-Guttin-Cluzel Siegfried, Wu Yingchun, et al.. Holography and micro-holography of particle fields: a numerical standard[J]. Opt Commun，2012，285 (13-14)：3013-3020.

[23] [23] Li Renxian, Han Xiang′e, Shi Lijuan, et al.. Debye series for Gaussian beam scattering by a multilayered sphere[J]. Appl Opt， 2007， 46 (21)： 4804-4812.

[24] [24] Collins J, Stuart A. Lens-system diffraction integral written in terms of matrix optics[J]. J Oot Soc Am，1970，60 (9)：1168-1177.

[25] [25] Verrier Nicolas, Coetmellec Sébastien, Brunel Marc, et al.. Digital in-line holography with an elliptical, astigmatic Gaussian beam: wide-angle reconstruction[J]. J Opt Soc Am A，2008，25 (6)：1459-1466.

[26] [26] Wen J J, Breazeale M A. A diffraction beam field expressed as the superposition of Gaussian beams[J]. J Acoust Soc Am， 1988，83(5): 1752-1756.

[27] [27] Nicolas F, Coetmellec S, Brunel M, et al.. Application of the fractional Fourier transformation to digital holography recorded by an elliptical, astigmatic Gaussian beam[J]. J Opt Soc Am A，2005，22 (11)：2569-2577.

[28] [28] Wu Xuecheng, Wu Yingchun, Yang Jing, et al.. Modified convolution method to reconstruct particle hologram with an elliptical Gaussian beam illumination[J]. Opt Express，2013，21 (10)：12803-12814.

[29] [29] Verrier Nicolas, Coetmellec Sébastien, Brunel Marc, et al.. Digital in-line holography in thick optical systems: application to visualization in pipes[J]. Appl Opt，2008，47 (22)：4147-4157.

[30] [30] Tyler Ga,Thompson B J. Fraunhofer holography applied to particle size analysis a reassessment[J]. J Modern Optics，1976，23 (9)：685-700.

[31] [31] Chan K T, Leung T P, Li Y J. Holographic imaging of side-scattering particles[J]. Opt & Laser Technol，1996，28 (8)：565-571.

[32] [32] Pu Ye, Meng H. An advanced off-axis holographic particle image velocimetry (HPIV) system[J]. Exp Fluids，2000，29 (2)：184-197.

[33] [33] Pu Y, Song X, Meng H. Off-axis holographic particle image velocimetry for diagnosing particulate flows[J]. Exp Fluids，2000，29 (7)：S117-S128.

[34] [34] Shen H, Brunel M, Coetmellec S, et al.. Glare point reconstruction in digital holographic microscopy for droplet characterization[C]. Progress In Electromagnetics Research Symposium Proceedings, 2011, 7(6): 567-570.

[35] [35] Wu X, GreHan G, Meunier-Guttin-Cluzel S, et al.. Numerical investigation of near-field off-axis scattering in-line recording particle holography[C]. 15th Int Symp on Applications of Laser Techniques to Fluid Mechanics, 2010. 1-9.

[36] [36] Kreis Thomas. Handbook of Holographic Interferometry: Optical and Digital Methods[M]. Wiley-VCH Verlag GmbH & Co. KGaA, 2005. 81-183.

[37] [37] De Nicola S, Ferraro P, Finizio A, et al.. Correct-image reconstruction in the presence of severe anamorphism by means of digital holography[J]. Opt Lett，2001，26 (13)：974-976.

[38] [38] Lebrun Denis, Belad Samir, Zkul Cafer. Hologram reconstruction by use of optical wavelet transform[J]. Appl Opt，1999，38 (17)：3730-3734.

[39] [39] Liebling M, Blu T, Unser M. Fresnelets: new multiresolution wavelet bases for digital holography[J]. IEEE Transactions on Image Processing, 2003，12(1)：29-43.

[40] [40] Remacha Clément, Coetmellec Sébastien, Brunel Marc, et al.. Extended wavelet transformation to digital holographic reconstruction: application to the elliptical, astigmatic Gaussian beams[J]. Appl Opt，2013，52(4)：838-848.

[41] [41] Wu Xuecheng, Wu Yingchun, Zhou Binwu, et al.. Asymmetric wavelet reconstruction of particle hologram with an elliptical Gaussian beam illumination[J]. Appl Opt，2013，52(21)：5065-5071.

[42] [42] Coetmellec Sébastien, Lebrun Denis, Zkul Cafer. Characterization of diffraction patterns directly from in-line holograms with the fractional Fourier transform[J]. Appl Opt， 2002，41(2)：312-319.

[43] [43] Coetmellec Sébastien, Lebrun Denis, Zkul Cafer. Application of the two-dimensional fractional-order Fourier transformation to particle field digital holography[J]. J Opt Soc Am A，2002，19(8)：1537-1546.

[44] [44] Zhang Y, Pedrini G, Osten W, et al.. Applications of fractional transforms to object reconstruction from in-line holograms[J]. Opt Lett，2004，29(15): 1793-1795.

[45] [45] Onural L. Diffraction from a wavelet point of view[J]. Opt Lett，1993，18 (11)：846.

[46] [46] Malek M, Coetmellec S, Allano D, et al.. Formulation of in-line holography process by a linear shift invariant system: application to the measurement of fiber diameter[J]. Opt Commun，2003，223 (4-6)：263-271.

[47] [47] Coetmellec S, Verrier N, Brunel M, et al.. General formulation of digital in-line holography from correlation with a chirplet function[J]. J European Optical Society-Rapid Publications, 2010, 5: 10027.

[48] [48] Wu Yingchun,Wu Xuecheng,Wang Zhihua, et al.. Reconstruction of digital inline hologram with compressed sensing[J]. Acta Optica Sinica, 2011, 31(11): 1109001.

[49] [49] De Nicola Sergio, Finizio A, Pierattini G, et al.. Angular spectrum method with correction of anamorphism for numerical reconstruction of digital holograms on tilted planes[J]. Opt Express，2005，13 (24)：9935-9940.

[50] [50] Yingchun Wu, Xuecheng Wu, Jing Yang, et al.. Wavelet-based depth-of-field extension, accurate autofocusing and particle pairing for digital inline particle holography[J]. Appl Opt，2014, 53(4): 556-564.

[51] [51] Singh Dhananjay Kumar, Panigrahi P K. Automatic threshold technique for holographic particle field characterization[J]. Appl Opt，2012，51 (17)：3874-3887.

[52] [52] Tian L, Loomis N, Domínguez-Caballero J A, et al.. Quantitative measurement of size and three-dimensional position of fast-moving bubbles in air-water mixture flows using digital holography[J]. Appl Opt，2010，49 (9)：1549-1554.

[53] [53] Wu Y, Wu X, Wang Z, et al.. Coal powder measurement by digital holography with expanded measurement area[J]. Appl Opt，2011，50 (34)： H22-H29.

[54] [54] Sato Akira, Pham Quang Duc, Hasegawa Satoshi, et al.. Three-dimensional subpixel estimation in holographic position measurement of an optically trapped nanoparticle[J]. Appl Opt，2013，52 (1)：A216-A222.

[55] [55] Ilchenko V, Lex T, Sattelmayer T. Depth position detection of the particles in digital holographic particle image velocimetry (DHPIV)[C]. SPIE, 2005, 5851: 123-128.

[56] [56] Chen W, Quan C, Tay C J. Extended depth of focus in a particle field measurement using a single-shot digital hologram[J]. Appl Phys Lett， 2009，95(20): 201103.

[57] [57] Choo Y J, Kang B S. The characteristics of the particle position along an optical axis in particle holography[J]. Meas Sci & Technol，2006，17(4): 761-770.

[58] [58] Soontaranon S, Widjaja J, Asakura T. Extraction of object position from in-line holograms by using single wavelet coefficient[J]. Opt Commun，2008，281(6)：1461-1467.

[59] [59] Liebling M, Unser M. Autofocus for digital Fresnel holograms by use of a Fresnelet-sparsity criterion[J]. J Opt Sci Am A，2004，21(12)：2424-2430.

[60] [60] Boucherit Sebti, Bouamama Larbi, Benchickh Halim, et al.. Three-dimensional solid particle positions in a flow via multiangle off-axis digital holography[J]. Opt Lett，2008，33(18)：2095-2097.

[61] [61] Moreno-Hernandez D, Andres B G, et al.. 3D particle positioning by using the Fraunhofer criterion[J]. Opt & Lasers in Eng，2011， 49(6): 729-735.

[62] [62] Darakis Emmanouil, Khanam Taslima, Rajendran Arvind, et al.. Microparticle characterization using digital holography[J]. Chem Eng Sci，2010，65(2)：1037-1044.

[63] [63] Yang Yan, Kang Boseon. Measurements of the characteristics of spray droplets using in-line digital particle holography[J]. J Mechanical Science and Technology，2009，23(6)：1670-1679.

[64] [64] Palero Virginia, Arroyo M, Soria Julio. Digital holography for micro-droplet diagnostics[J]. Exp Fluids，2007，43(2)：185-195.

[65] [65] Lü Qieni, Zhao Chen, Ma Zhibin, et al.. Digital holography experiment on the measurement of particle size and size distribution of diesel spray[J]. Chinese J Lasers, 2010, 37(3): 779-783.

[66] [66] Talapatra S, Sullivan J, Katz J, et al.. Application of in-situ digital holography in the study of particles, organisms and bubbles within their natural environment[C]. SPIE, 2012, 8372: 837205.

[67] [67] Lee Sang-Hyuk, Roichman Yohai, Yi Gi-Ra, et al.. Characterizing and tracking single colloidal particles with video holographic microscopy[J]. Opt Express，2007，15(26)：18275-18282.

[68] [68] Wu X, Gréhan G, Meunier-Guttin-Cluzel S, et al.. Sizing of particles smaller than 5 μm in digital holographic microscopy[J]. Opt Lett，2009，34 (6)：857-859.

[69] [69] Dubois Frank, Grosfils Patrick. Dark-field digital holographic microscopy to investigate objects that are nanosized or smaller than the optical resolution[J]. Opt Lett，2008，33 (22)：2605-2607.

[70] [70] Berg M J, Videen G. Digital holographic imaging of aerosol particles in flight[J]. J Quant Spectrosc Radiat Transfer，2011， 112(11): 1776-1783.

[71] [71] Abrantes Juliana K, Stanislas Michel, Coudert Sébastien, et al.. Digital microscopic holography for micrometer particles in air[J]. Appl Opt，2013，52 (1)：A397-A409.

[72] [72] Choi Y S, Lee S J. Three-dimensional volumetric measurement of red blood cell motion using digital holographic microscopy[J]. Appl Opt，2009，48 (16)：2983-2990.

[73] [73] Caprio G Di, Coppola G, Grilli S, et al.. Microfluidic system based on the digital holography microscope for analysis of motile sperm[C]. SPIE, 2009, 7389: 738907.

[74] [74] Sheng Jian, Malkiel Edwin, Katz Joseph. Digital holographic microscope for measuring three-dimensional particle distributions and motions[J]. Appl Opt，2006，45 (16)：3893-3901.

[75] [75] Sheng J, Malkeil E, Katz J. Using digital holographic microscopy for simultaneous measurements of 3D near wall velocity and wall shear stress in a turbulent boundary layer[J]. Exp Fluids，2008，45(6): 1023-1035.

[76] [76] Yang Y, Li G Y, Tang L L, et al.. Integrated gray-level gradient method applied for the extraction of three-dimensional velocity fields of sprays in in-line digital holography[J]. Appl Opt, 2012， 51(2)： 255-267.

[77] [77] Li Guangyong, Yang Yan. Digital holography particle image velocimetry applied for measurement of the rotating flow fields[J]. Chinese J Lasers, 2012, 39(6): 0609001.

[78] [78] Satake Shin-Ichi, Kunugi Tomoaki, Sato Kazuho, et al.. Three-dimensional flow tracking in a micro channel with high time resolution using micro digital-holographic particle-tracking velocimetry[J]. Opt Rev, 2005， 12 (6)：442-444.

[79] [79] Kim Seok, Lee Sang Joon. Measurement of dean flow in a curved micro-tube using micro digital holographic particle tracking velocimetry[J]. Exp Fluids，2009，46(2): 255-264.

[80] [80] Allano Daniel, Malek Mokrane, Walle Franoise, et al.. Three-dimensional velocity near-wall measurements by digital in-line holography: calibration and results[J]. Appl Opt，2013，52 (1)：A9-A17.

[81] [81] Sheng J, Meng H. A genetic algorithm particle pairing technique for 3D velocity field extraction in holographic particle image velocimetry[J]. Exp Fluids，1998，25(5-6): 461-473.

[82] [82] Shen Gongxin, Wei Runjie. Digital holography particle image velocimetry for the measurement of 3Dt-3c flows[J]. Opt & Lasers in Eng， 2005，43(10)：1039-1055.

[83] [83] Pu Ye, Meng Hui. Four-dimensional dynamic flow measurement by holographic particle image velocimetry[J]. Appl Opt， 2005，44 (36)：7697-7708.

[84] [84] Tao Bo, Katz Joseph, Meneveau Charles. Geometry and scale relationships in high Reynolds number turbulence determined from three-dimensional holographic velocimetry[J]. Phys Fluids，2000，12 (5)：941-944.

[85] [85] De Jong J, Salazar J P L C, Woodward S, et al.. Measurement of inertial particle clustering and relative velocity statistics in isotropic turbulence using holographic imaging[J]. Int J Multiphase Flow，2010，36(4)： 324-332.

[86] [86] Satake S, Anraku T, Kanamori H, et al.. Measurements of three-dimensional flow in microchannel with complex shape by micro-digital-holographic particle-tracking-velocimetry[J]. J Heat Transfer, 2008，130 (4)： 042413.

[87] [87] Wu Y, Wu X, Wang Z, et al.. Measurement of microchannel flow with digital holographic microscopy by integrated nearest neighbor and cross-correlation particle pairing[J]. Appl Opt, 2011，50(34)：H297-H305.

[88] [88] Cheong Fook Chiong, Sun Bo, Dreyfus R, et al.. Flow visualization and flow cytometry with holographic video microscopy[J]. Opt Express，2009，17(15)： 13071-13079.

[89] [89] Meng Hui, Hussain Fazle. Holographic particle velocimetry: a 3D measurement technique for vortex interactions, coherent structures and turbulence[J]. Fluid Dynamics Research，1991，8(1-4)： 33-52.

[90] [90] Jones B, Meng H. Nonequilibrium Turbulence Study Using Holographic Particle Image Velocimetry[R]. A087793, 2001.