[1] Gabor, D. A new microscopic principle. Nature 161, 777-778 (1948). doi: 10.1038/161777a0
[2] Leith, E. N. & Upatnieks, J. New techniques in wavefront reconstruction. Journal of the Optical Society of America 51, 1469-1473 (1961).
[3] Maiman, T. H. Stimulated optical radiation in ruby. Nature 187, 493-494 (1960). doi: 10.1038/187493a0
[4] Denisyuk, Y. N. On the reflection of optical properties of an object in the wave field of light scattered by it. Doklady Akademii Nauk SSSR 144, 1275-1278 (1962).
[5] Brown, B. R. & Lohmann, A. W. Complex spatial filtering with binary masks. Applied Optics 5, 967-969 (1966). doi: 10.1364/AO.5.000967
[6] Stetson, K. A. & Powell, R. L. Hologram interferometry. Journal of the Optical Society of America 56, 1161-1163 (1966). doi: 10.1364/JOSA.56.001161
[7] Gabor, D. Physics 1971-1980. Nobel Lecture, Lundqvist, S. Ed. , World Scientific Publishing Co. , Singapore (1992) dedicated to the award of the Nobel Prize in 1971.
[8] Goodman, J. W. & Lawrence, R. W. Digital image formation from electronically detected holograms. Applied Physics Letters 11, 77-79 (1967). doi: 10.1063/1.1755043
[9] Huang, T. S. Digital holography. Proceedings of the IEEE 59, 1335-1346 (1971). doi: 10.1109/PROC.1971.8408
[10] McGovern, A. J. & Wyant, J. C. Computer generated holograms for testing optical elements. Applied Optics 10, 619-624 (1971). doi: 10.1364/AO.10.000619
[11] Leendertz, J. A. Interferometric displacement measurement on scattering surfaces utilizing speckle effect. Journal of Physics E:Scientific Instruments 3, 214-218 (1970). doi: 10.1088/0022-3735/3/3/312
[12] Butters, J. N. & Leendertz, J. A. Holographic and Video techniques applied to engineering measurement. Measurement and Control 4, 349-354 (1971). doi: 10.1177/002029407100401201
[13] Stetson, K. A. The discovery of holographic interferometry, its development and applications. Light:Advanced Manufacturing 3, 2 (2022).
[14] Trolinger, J. D. The language of holography. Light:Advanced Manufacturing 2, 34 (2021).
[15] de Groot, P. J. et al. Contributions of holography to the advancement of interferometric measurements of surface topography. Light:Advanced Manufacturing 3, 7 (2022).
[16] Sirohi, R. Shearography and its applications–a chronological review. Light:Advanced Manufacturing 3, 4 (2022).
[17] Osten, W. & Pedrini, G. 55 Years of Holographic Non-Destructive Testing and Experimental Stress Analysis: Is there still Progress to be expected. Light:Advanced Manufacturing 3, 8 (2022).
[18] Häusler, G. & Willomitzer, F. Reflections about the holographic and non-holographic acquisition of surface topography: where are the limits. Light:Advanced Manufacturing 3, 25 (2022).
[19] Fratz, M. et al. Digital holography in production: an overview. Light:Advanced Manufacturing 2, 15 (2021).
[20] Claus, D. et al. Snap-shot topography measurement via dual-VCSEL and dual wavelength digital holographic interferometry. Light:Advanced Manufacturing 2, 29 (2021).
[21] Schnars, U. & Falldorf, C. Parallax limitations in digital holography: a phase space approach. Light:Advanced Manufacturing 3, 28 (2022).
[22] Gao, P. & Yuan, C. Resolution enhancement of digital holographic microscopy via synthetic aperture: a review. Light:Advanced Manufacturing 3, 6 (2022).
[23] Kim, M. K. Phase microscopy and surface profilometry by digital holography. Light:Advanced Manufacturing 3, 19 (2022).
[24] Utadiya, S. et al. Integrated self-referencing single shot digital holographic microscope and optical tweezer. Light:Advanced Manufacturing 3, 37 (2022).
[25] Schelkens, P. et al. Compression strategies for digital holograms in biomedical and multimedia applications. Light:Advanced Manufacturing 3, 40 (2022).
[26] Wang, Z. et al. Digital holography as metrology tool at micro-nanoscale for soft matter. Light:Advanced Manufacturing 3, 10 (2022).
[27] Kress, B. C. et al. Holographic optics in planar optical systems for next generation small form factor mixed reality headsets. Light:Advanced Manufacturing 3, 42 (2022).
[28] Du, Y. et al. Hybrid multimode – multicore fibre fordeep-tissue neurophotonics. Light:Advanced Manufacturing 3, 29 (2022).
[29] Abdurashitov, A. S. et al. Integrated binary hologram to monitor cargo release from a drug-eluting film. Light:Advanced Manufacturing 3, 30 (2022).
[30] Choporova, Y., Knyazev, B. & Pavelyev, V. Holography with high-power CW coherent terahertz source: optical components, imaging, and applications. Light:Advanced Manufacturing 3, 31 (2022).
[31] Stark, A. W. et al. Miniaturization of a coherent monocular structured illumination system for future combination with digital holography. Light:Advanced Manufacturing 3, 34 (2022).
[32] Petrov, N. V. et al. Design of broadband terahertz vector and vortex beams: I. Review of materials and components. Light:Advanced Manufacturing 3, 43 (2022).
[33] Petrov, N. V. et al. Design of broadband terahertz vector and vortex beams: II. Holographic assessment. Light:Advanced Manufacturing 3, 44 (2022).
[34] Zepp, A. et al. Simulation-based design optimization of the holographic wavefront sensor in closed-loop adaptive optics. Light:Advanced Manufacturing 3, 27 (2022).
[35] Zhou, H., Hussain, M. M. & Banerjee, P. P. A review of the dual-wavelength technique for phase imaging and 3D topography. Light:Advanced Manufacturing 3, 17 (2022).
[36] Hartlieb, S. et al. Multi-positional image-based vibration measurement by holographic image replication. Light:Advanced Manufacturing 2, 32 (2021).
[37] Piniard, M. et al. Melt pool monitoring in laser beam melting with two-wavelength holographic imaging. Light:Advanced Manufacturing 3, 11 (2022).
[38] Tornari, V. A symmetry concept and significance of fringe patterns as a direct diagnostic tool in artwork conservation. Light:Advanced Manufacturing 3, 18 (2022).
[39] Georges, M., Zhao, Y. & Vandenrijt, J. F. Holography in the invisible. From the thermal infrared to the terahertz waves: outstanding applications and fundamental limits. Light:Advanced Manufacturing 2, 22 (2022).
[40] Koukourakis, N. et al. Investigation of human organoid retina with digital holographic transmission matrix measurements. Light:Advanced Manufacturing 3, 23 (2022).
[41] Shanmugam, P. et al. Variable shearing holography with applications to phase imaging and metrology. Light:Advanced Manufacturing 3, 16 (2022).
[42] Tang, H. et al. Ultra-high speed holographic shape and displacement measurements in the hearing sciences. Light:Advanced Manufacturing 3, 15 (2022).
[43] Hall, M. L. et al. The application of digital holography for accurate three-dimensional localisation of mosquito-bednet interaction. Light:Advanced Manufacturing 3, 20 (2022).
[44] Hasegawa, S. et al. In-process monitoring in laser grooving with line-shaped femtosecond pulses using optical coherence tomography. Light:Advanced Manufacturing 3, 33 (2022).
[45] Blanche, P. A. Holography, and the future of 3D display. Light:Advanced Manufacturing 2, 28 (2021).
[46] Sando, Y. et al. Holographic augmented reality display with conical holographic optical element for wide viewing zone. Light:Advanced Manufacturing 3, 12 (2022).
[47] Blinder, D. et al. The state-of-the-art in computer generated holography for 3D display. Light:Advanced Manufacturing 3, 35 (2022).
[48] Park, J. H. & Lee, B. Holographic techniques for augmented reality and virtual reality near-eye displays. Light:Advanced Manufacturing 3, 9 (2022).
[49] Takeda, M., Osten, W. & Watanabe, E. Holographic 3D Imaging through Random Media: Methodologies and Challenges. Light:Advanced Manufacturing 3, 14 (2022).
[50] Anand, V., Rosen, J. & Juodkazis, S. Review of engineering techniques in chaotic coded aperture imagers. Light:Advanced Manufacturing 3, 24 (2022).
[51] Situ, G. Deep holography. Light:Advanced Manufacturing 3, 13 (2022).