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Multi-view Display with Hologram Screen using Three-dimensional Bragg Diffraction  

Okamoto, Masaaki (Laboratories of Image Information Science and Technology)
Shimizu, Eiji (Department of Electrical Engineering, Osaka City University)
Publication Information
Journal of Information Display / v.3, no.3, 2002 , pp. 1-11 More about this Journal
Abstract
Multi-view function is important to three-dimensional displays without dedicated glasses. It is the reason that the observers earnestly desire to change their positions freely. Multi-viewing is also principal to the reality of three-dimensional (3D) image displayed on the screen. The display of projection type has the advantage that the number of viewing points can be easily increased according to the number of projectors. The authors research on multi-view projection display with hologram screen. Powerful directionality of the diffracted beam from hologram screen is required unlike two-dimensional (2D) display. We developed a new method that all diffracted beams satisfied the same Bragg condition and became sufficiently bright to observe the 3D image under usual indoor light. The principle is based on the essential Bragg diffraction in the three-dimensional space. Owing to such three-dimensional Bragg diffraction we achieved an excellent hologram screen that could be multiple reconstructed in spite of single recording. This hologram screen is able to answer arbitrary numbers of viewing points within wide viewing zone. The distortion of 3D image becomes also sufficiently small with the method of dividing the cross angle between illumination and diffraction beam.
Keywords
multi-view display; 3D display; hologram screen; bragg diffraction;
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1 K. Taima, H. Ueda, H. Okamoto, T. kubota, Y. kajiki, T. Nakamura, H. Nishida, H. Takahashi, and E. Shimizu, Proc. SPIE, 2176, 23 (1994)   DOI
2 J. H. Kulick, S. T. Kowel, G. P. Nordin, A. Parker, R. Lindquist, P. Nasiatka, and M. Jones, Proc. SPIE, 2176, 2 (1994)   DOI
3 C. Newswanger, U. S. Patent 4799739, (Jan. 24, 1989)
4 M. Okamoto, T. Ando, K. Yamasaki, and E. Shimizu, Proc. 3D Image Conference '99, 99 (1999) [in Japanese]
5 M. Okamoto and E. Shimizu, J. of the Institute of Image Electronics Engineers of Japan, 31(1), 43 (2002). [in Japanese]
6 W. L. Bragg, Nature, 143, 678 (1939)   DOI
7 W. L. Bragg, Nature, 149, 470 (1942)   DOI
8 H. I. Bjelkhagen, Silver-Halide Recording Materials for Holography and Their Processing, Sphnger-Verlag (1993)
9 T. Toda, S. Takahashi, and F. Iwata, Proc. SPIE, 2406, 191 (1995)
10 M. Okamoto, T. Ando, K. Yamasaki, and E. Shimizu, Proc. SPIE, 3956, 64 (2000)   DOI
11 M. Okamoto, K. Yamasaki, and E. Shimizu, Proc. SPIE, 3293,48 (1998)   DOI
12 K. Ohnuma and F. Iwata, Appl. Opt., 27(18), 3859 (1988)   DOI
13 M, Shires, Proc. SPIE, 2333, 381 (1994)
14 M. Okamoto, Z. Wei, and E. Shimizu, Proc. 3D Image Conference 2001, 125 (2001). [in Japanese]
15 G. Saxby, Practical Holography, Prentice Hall, (Second Edition, 1994)
16 K. Sakamoto, H. Takahashi, E. Shimizu, H. Ueda, K. Tanaka, and M. Okamoto, Proc. SPIE, 3011, 36 (1997)   DOI
17 H. Kogelnik, The Bell System Technical J., 48(9), 2909 (1969)   DOI
18 E. G. Ramberg, RCA Rev., 27, 467 (1966)
19 D. Trayner and E. Orr, Proc. SPIE, 2653, 65 (1996)   DOI
20 P. Hariharan, Optical Holography, Cambridge University Press (Second Edition, 1996)
21 E. B. Champagne, J. Opt. Soc. Am., 57(1), 51 (1967)   DOI
22 J. S. Kollin, S. A. Benton, and M. L. Jepsen, Proc. SPIE, 1136, 178(1989)
23 S. A. Benton, International Symposium on Display Holography, 3, 593 (1988)
24 M. Okamoto and E. Shimizu, HODIC Circular, 21(4), 7 (2001). [in japanese]
25 M. Okamoto and E.Shimizu, Proc. 2nd IMID, 1005(2002)
26 N. Hashimoto, K. Hoshino, and S. Morokawa, Proc. SPIE, 1667, 2 (1992)   DOI