Digital Holography

Yaping Zhang; Ting-Chung Poon

doi:10.1017/9781009053204.007

6 - Digital Holography

Published online by Cambridge University Press: 22 December 2022

Yaping Zhang and

Ting-Chung Poon

Show author details

Yaping Zhang: Affiliation:
Kunming University of Science and Technology, China
Ting-Chung Poon: Affiliation:
Virginia Polytechnic Institute and State University

Book contents

Get access

Summary

Film-based holography employs the use of high-resolution films such as the use of photopolymers or photorefractive materials for recording. These materials, while having high resolution, have a couple of drawbacks. The film-based techniques are typically slow for real-time applications and difficult to allow direct access to the recorded hologram for manipulation and subsequent processing. With recent advances in high-resolution solid-state 2-D sensors and the availability of ever-increasing power of computers and digital data storage capabilities, holography coupled with electronic/digital devices has become an emerging technology with an increasing number of applications such as in metrology, nondestructive testing, and 3-D imaging. While electronic detection of holograms by a TV camera was first performed by Enloe et al. in 1966, hologram numerical reconstruction was initiated by Goodman and Lawrence. In digital holography, it has meant that holographic information of 3-D objects is captured by a CCD, and reconstruction of holograms is subsequently calculated numerically. Nowadays, digital holography means the following situations as well. Holographic recording is done by an electronic device, and the recorded hologram can be numerically reconstructed or sent to a display device (called a spatial light modulator) for optical reconstruction. Or, hologram construction is completely numerically simulated. The resulting hologram is sent subsequently to a display device for optical reconstruction. This aspect of digital holography is often known as computer-generated holography.

Keywords

coherent digital holography CCD limitations phase-shifting holography optical scanning holography Fresnel incoherent correlation holography,coded aperture imaging coded aperture correlation holography preprocessing in optical scanning holography computer-generated holography point-based approach to computer-generated holography polygone-based approach to computer generated holography

Type: Chapter
Information: Modern Information Optics with MATLAB , pp. 190 - 259

DOI: https://doi.org/10.1017/9781009053204.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2023

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ahrenberg, L., Benzie, P., Magnor, M., and Watson, J. (2008). “Computer generated holograms from three dimensional meshes using an analytic light transport model,” Applied Optics 47, pp. 1567-1574.CrossRef Google Scholar

Berrang, J. E. (1970). “Television transmission of holograms using a narrow-band video signal,” Bell System Technical Journal 49, pp. 879–887.Google Scholar

Burckhardt, C. B. and Enloe, L. H. (1969). “Television transmission of holograms with reduced resolution requirements on the camera tube,” Bell System Technical Journal 48, pp. 1529–1535.CrossRef Google Scholar

Cannon, T. M. and Fenimore, E. E. (1980). “Coded aperture imaging: many holes make light work,” Optical Engineering 19, pp. 283–289.CrossRef Google Scholar

Cochran, G. (1966). “New method of making Fresnel transforms with incoherent light,” Journal of the Optical Society of America 56, pp. 1513–1517.CrossRef Google Scholar

Dicke, R. H. (1968). “Scatter-hole camera for X-rays and gamma rays,” The Astrophysical Journal 153, L101.Google Scholar

Enloe, L. H., Murphy, J. A., and Rubinsten, C. B. (1966). “Hologram transmission via television,” Bell System Technical Journal 45, pp. 333–335.Google Scholar

Gabor, D. and Goss, P. (1966). “Interference microscope with total wavefront reconstruction,” Journal of the Optical Society of America 56, pp. 849–858.CrossRef Google Scholar

Goodman, J. W. and Lawrence, R.W. (1967). “Digital image formation from electronically detected holograms,” Applied Physics Letters 11, pp. 77–79.CrossRef Google Scholar

Guo, P. and Devane, A. J. (2004), “Digital microscopy using phase-shifting digital holography with two reference waves,” Optics Letters 29, pp. 857–859.CrossRef Google Scholar

Indebetouw, G., Kim, T., Poon, T.-C., and Schilling, B. W. (1998). “Three-dimensional location of fluorescent inhomogeneities in turbid media by scanning heterodyne holography,” Optics Letters 23, pp.133–137.CrossRef Google Scholar

Indebetouw, G. and Zhong, W. (2006). “Scanning holographic microscopy of three-dimensional holographic microscopy,” Journal of the Optical Society of America A 23, pp. 2657–2661.CrossRef Google Scholar

Kim, H., Hahn, J., and Lee, B. (2008). “Mathematical modeling of triangle-mesh-modeled three-dimensional surface objects for digital holography,” Applied Optics 47, pp. D117–D127.Google Scholar

Kim, T. and Kim, T. (2020). “Coaxial scanning holography,” Optics Letters 45, pp. 2046–2049.CrossRef Google Scholar

Liu, J.-P., Chen, W.-T., Wen, H.-H. and Poon, T.-C. (2020). “Recording of a curved digital hologram for orthoscopic real image reconstruction,” Optics Letters 45, pp. 4353–4356.CrossRef Google Scholar

Liu, J.-P., Tahara, T., Hayasaki, Y., and Poon, T.-C. (2018). “Incoherent digital holography: a review,” Applied Sciences 8 (1), 143.CrossRef Google Scholar

Liu, J.-P. and Poon, T.-C. (2009). “Two-step-only quadrature phase-shifting digital holography,” Optics Letters 34, pp.250–252.CrossRef Google Scholar

Liu, J. -P., Poon, T.-C., Jhou, G.-S., and Chen, P.-J. (2011). “Comparison of two-, three-, and four-exposure quadrature phase-shifting holography,” Applied Optics 50, pp.2443–2450.CrossRef Google Scholar

Liu, J.-P., Guo, C.-H.,Hsiao, W.-J., Poon, T.-C., and Tsang, P. (2015). “Coherence experiments in single-pixel digital holography,” Optics Letters 40, pp. 2366–2369.Google Scholar

Lohmann, A. W. (1965). “Wavefront reconstruction for incoherent objects,” Journal of the Optical Society of America 55, pp. 1555–1556.Google Scholar

Meng, X.F., Cai, L. Z., Xu, X. F., Yang, X. L., Shen, X. X., Dong, G. Y., and Wang, Y. R. (2006). “Two-step phase-shifting interferometry and its application in image encryption,” Optics Letters 31, pp.1414–1416.Google Scholar

Matsushima, K. (2020). Introduction to Computer Holography Creating Computer-Generated Holograms as the Ultimate 3D Image, Springer, Switzerland.Google Scholar

Mertz, L. (1964). “Metallic beam splitters in interferometry,” Journal of the Optical Society of America, No. 10, Advertisement vii.Google Scholar

Mertz, L. and Young, N. O. (1962). “Fresnel transformations of images,” in Habell, K. J., ed., Proceedings of the Conference on Optical Instruments and Techniques, pp. 305–310. Wiley and Sons, New York.Google Scholar

Molesini, G., Bertani, D., and Cetca, M. (1982). “In-line holography with interference filters as Fourier processor,” Optica Acta: International Journal of Optics 29, pp. 497–485.Google Scholar

Phan, A.-H., Piao, M.-L., Gil, S.K. and Kim, N. (2014a). “Generation speed and reconstructed image quality enhancement of a long-depth object using double wavefront recording planes and a GPU,” Applied Optics 53, pp. 4817–4824.CrossRef Google Scholar

Phan, A.-H., Alam, M. A., Jeon, S.-H., Lee, J.-H., Kim, N. (2014b) “Fast hologram generation of long-depth object using multiple wavefront recording planes,” Proc. SPIE Vol. 9006, Practical Holography XXVIII: Materials and Applications, 900612.Google Scholar

Poon, T.-C. (1985). “Scanning holography and two-dimensional image processing by acousto-optic two-pupil synthesis,” Journal of the Optical Society of America A 2, pp. 521–527.CrossRef Google Scholar

Poon, T.-C. (2008). “Scan-free three-dimensional imaging,” Nature Photonics 2, pp. 131–132.Google Scholar

Poon, T.C. and Korpel, A. (1979). “Optical transfer function of an acousto-optic heterodyning image processor,” Optics Letters 4, pp. 317–319.Google Scholar

Poon, T.-C. and Banerjee, P. P. (2001). Contemporary Optical Image Processing with MATLAB®. Elsevier, United Kingdom.Google Scholar

Poon, T.-C. and Liu, J.-P. (2014). Introduction to Modern Digital Holography with MATLAB. Cambridge University Press, Cambridge, United Kingdom.CrossRef Google Scholar

Poon, T.-C. (2007). Optical Scanning Holography with MATLAB®. Springer, New York.CrossRef Google Scholar

Popescu, G. (2011). Quantitative Phase Imaging of Cells and Tissues. Springer, New York.Google Scholar

Rosen, J. and Brooker, G. (2007). “Digital spatially incoherent Fresnel holography,” Optics Letters 32, pp. 912–914.CrossRef Google Scholar

Rosen, J., Anand, V., Rai, M. R., Mukherjee, S., and Bulbul, A. (2019). “Review of 3D imaging by coded aperture correlation holography (COACH),” Applied Sciences 9, pp. 605.Google Scholar

Schilling, B. W. and Poon, T.-C. (1995). “Real-time preprocessing of holographic information,” Optical Engineering 34, pp. 3174–3180.Google Scholar

Schilling, B. W., Poon, T.-C., Indebetouw, G., Storrie, B., Shinoda, K, and Wu, M. (1997). “Three-dimensional holographic fluorescence microscopy,” Optics Letters 22, pp. 1506–1508.CrossRef Google Scholar

Schnars, U. and Jueptner, W. (2005). Digital Holography: Digital Hologram Recording, Numerical Reconstruction, and Related Techniques. Springer, Berlin.Google Scholar

Shimobaba, T. and Tto, T. (2019). Computer Holography Acceleration Algorithms and Hardware Implementations. CRC Press, Tayler & Francis Group, USA.CrossRef Google Scholar

Shimobaba, T., Masuda, N., and Ito, T. (2009). “Simple and fast calculation algorithm for computer-generated hologram with wavefront recording plane,” Optics Letters 34, pp.3133–3135.CrossRef Google Scholar

Shimobaba, T., Nakayama, H., Masuda, N., and Ito, T. (2010). “Rapid calculation algorithm of Fresnel computer-generated-hologram using look-up table and wavefront-recording plane methods for three-dimensional display,” Optics Express 18, pp.19504–19509.Google Scholar

Simpson, R.G., Barrett, H.H., Subach, J. A., and Fisher, H.D. (1975). “Digital processing of annular coded-aperture imagery,” Optical Engineering 14, pp. 490.Google Scholar

Tsai, C.-M., Sie, H.-Y., Poon, T.-C., and Liu, J.-P. (2021). “Optical scanning holography with a polarization directed flat lens,” Applied Optics 60, pp. B113–B118.Google Scholar

Tsang, P. W.M. and Poon, T.-C. (2013). “Review on theory and applications of wavefront recording plane framework in generation and processing of digital holograms,” Chinese Optics Letters 11, 010902.Google Scholar

Tsang, P., Cheung, W.-K., Poon, T.-C., and Zhou, C. (2011). “Holographic video at 40 frames per second for 4-million object points,” Optics Express 19, pp.15205–15211.Google Scholar

Tsang, P. W. M., Poon, T.-C., and Wu, Y. M. (2018). “Review of fast methods for point-based computer-generated holography [Invited],” Photonics Research 6, pp. 837–846.CrossRef Google Scholar

Vijayakumar, A., Kashter, Y., Kelner, R., and Rosen, J. (2016). “Coded aperture correlation holography - a renew type of incoherent digital holograms,” Optics Express 24, pp. 262634–262634.Google Scholar

Wang, Y., Zhen, Y., Zhang, H., and Zhang, Y. (2004). “Study on digital holography with single phase-shifting operation,” Chinese Optics Letters 2, pp.141–143.Google Scholar

Wu, J., Zhang, H., Zhang, W., Jin, G., Cao, L., and Barbastathis, G. (2020). “Single-shot lensless imaging with Fresnel zone aperture and incoherent illumination,” Light: Science & Applications 9 (1), p. 53.Google Scholar

Yeom, H.-J. and Park, J.H. (2016). “Calculation of reflectance distribution using angular spectrum convolution in mesh-based computer-generated hologram,” Optics Express 24, pp. 19801–19813.Google Scholar

Yoneda, N., Satia, Y., and Nomura, T. (2020). “Motionless optical scanning holography,” Optics Letters 45, pp. 3184–3187.Google Scholar

Yoneda, N., Satia, Y., and Nomura, T. (2020). “Spatially divided phase-shifting motionless optical scanning holography,” OSA Continuum 3, pp. 3523–3555.CrossRef Google Scholar

Yoshikawa, H., Yamaguchi, T., and Kitayama, R. (2009). In Digital Holography and Three-Dimensional Imaging, OSA Technical Digest (CD) (Optical Society of America, 2009), paper DWC4.Google Scholar

Zhang, Y., Poon, T.-C., Tsang, P. W. M., Wang, R., and Wang, L. (2019). “Review on feature extraction for 3-D incoherent image processing using optical scanning holography,” IEEE Transactions on Industrial informatics 15, pp.6146–6154.CrossRef Google Scholar

Zhang, Y., Wang, F., Poon, T.-C., Fan, S., and Xu, W. (2018). “Fast generation of full analytical polygon-based computer-generated holograms,” Optics Express 26, pp.19206–19224.CrossRef Google Scholar

Zhang, Y., Wang, R., Tsang, P. W. M., and Poon, T.-C. (2020),“Sectioning with edge extraction in optical incoherent imaging processing,” OSA Continuum 3, pp. 698–708.Google Scholar

Zhang, Y., Fan, H., Wang, F., Gu, X., Qian, X., and Poon, T.-C. (2022), “Polygon-based computer-generated holography: a review of fundamentals and recent progress [Invited],” Applied Optics 61, pp. B363–B374.Google Scholar

Book contents

6 - Digital Holography

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive