Abstract
Holography is an imaging technique to reconstruct wavefront information of the light scattered by real objects or a scene, allowing an observer to perceive three-dimensional (3D) images with the unassisted eye. Such 3D holographic images result from reproducing the intensity and phase of light by diffraction. This paper presents a temporal consistency enhancement for digital holographic video. The proposed temporal consistency enhancement method improves compression efficiency and visual quality by reducing the flickering artifact.
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References
Gabor, D.: A new microscopic principle. Nature 161(4098), 777–778 (1948)
Park, M., Chae, B.G., Kim, H.-E., Hahn, J., Kim, H., Park, C.H., Moon, K., Kim, J.: Digital holographic display system with large screen based on viewing window movement for 3D video service. ETRI J. 36(2), 232–241 (2014)
Chung, J.K., Tsai, M.H.: Three-Dimensional Holographic Imaging. John Wiley & Sons Inc, New York (2002)
Yoshikawa, H., Tamai, J.: Holographic image compression by motion picture coding. Proc. of SPIE 2652, 2–9 (1996)
Seo, Y.H., Choi, H.J., Kim, D.W.: 3D scanning-based compression technique for digital hologram video. Signal Process. 22(2), 144–156 (2007)
Naughton, T.J., Javidi, B.: Compression of encrypted three dimensional objects using digital holography. Opt. Eng. 43(10), 2233–2238 (2004)
Shortt, A., Naughton, T.J., Javidi, B.: Histogram approaches for lossy compression of digital holograms of three-dimensional objects. IEEE Trans. Imag. Proc. 16(6), 1548–1556 (2007)
Kayser, D., Javidi, B., Psaltis, D.: Compression of digital holographic data using its electromagnetic field properties. Opt. Inf. Syst. III, Proc. SPIE 5908, 97–105 (2005)
Ding, L., Yan, Y., Xue, Q., Jin, G.: Wavelet packet compression for volume holographic image recognition. Opt. Commun. 216, 105–113 (2003)
Liebling, M., Blu, T., Unser, M.: Fresnelets: new multiresolution wavelet bases for digital holography. IEEE Trans. Image Process. 12, 29–43 (2003)
Waters, J.P.: Holographic image synthesis utilizing theoretical methods. Appl. Phys. Lett. 9(11), 405–406 (1966)
Brown, B.R., Lohmann, A.W.: Complex spatial filtering with binary masks. Appl. Opt. 5, 967–969 (1966)
Goodman, J.W.: Introduction to Fourier Optics. Roberts and Company (2005)
Shortt, A., Naughton, T.J., Javidi, B.: Combined optimal quantization and lossless coding of digital holograms of three-dimensional objects. In: Three-Dimensional TV, Video, and Display V, Proceedings of SPIE vol. 6392, no. 63920A, October 2006
ITU-T SG16 Q.6, An excel add-in for computing Bjøntegaard metric and its evolution. VCEG-AE07, January 2007
Acknowledgment
This research was supported by GigaKOREA project, (GK15D0100, Development of Telecommunications Terminal with Digital Holographic Table-top Display).
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Oh, KJ., Choo, HG., Kim, J. (2015). Temporal Consistency Enhancement for Digital Holographic Video. In: Ho, YS., Sang, J., Ro, Y., Kim, J., Wu, F. (eds) Advances in Multimedia Information Processing -- PCM 2015. PCM 2015. Lecture Notes in Computer Science(), vol 9315. Springer, Cham. https://doi.org/10.1007/978-3-319-24078-7_63
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DOI: https://doi.org/10.1007/978-3-319-24078-7_63
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