662                  11. Information Display with Optics
       whereas in 3-D applications, holographic information has been acquired with
       the help of AOMs, as in the case of optical scanning holography. In addition,
       3-D displays using an AOM have been used in synthetic aperture holography.
       Spatial light modulators based on the use of the electro-optic effect have also
       been discussed. Specifically, electron-beam-addressed SLMs and parallel-alig-
       ned nematic liquid crystal SLMs have been emphasized and they have been
       used for 3-D holographic display as well. While applications involving SLMs
       are abundant [45], large high-resolution 2-D displays still present a challeng-
       ing problem [14,17] and large 3-D displays with sizable viewing angles remain
       formidable. This becomes one of the ultimate problems in modern optics, as
       current SLMs are not suitable for such applications due mainly to their limited
       spatial resolution and size.




       REFERENCES



       11.1 A. Korpel, 1981, "Acousto-optics — A Review of Fundamentals," Proc. IEEE, 69, 48-53.
       11.2 P. K, Das and C. M. Decusatis, Acousto-Optic Signal Processing: Fundamentals and
           Applications, Artech House, Boston, 1991.
       11.3 A. Vanderlugt, Optical Signal Processing, John Wiley and Sons, Inc., New York, 1992.
       11.4 P. Debye and F. W. Sears, 1932, "On the Scattering of Light by Supersonic Waves," Proc.
           Nat. Acad. Sci., 18, 409-414.
       11.5 C. V. Raman and N .S. N. Nath, 1935; 1936, "The Diffraction of Light by High-Frequency
           Sound Waves," Proc. Ind. Acad. Sci., 2, 406-420; 3, 75-84, 119-125, 259-465.
       11.6 R. R. Aggarwal, 1950, "Diffraction of Light by Ultrasonic Waves (Deduction of Different
           Theories for the Generalized Theory of Raman and Nath)," Proc. Ind. Acad. Sci. ,431,
           417-426.
       11.7 R. Adler, 1967, "Interaction between Light and Sound," IEEE Spectrum, 4(5), 42-54.
       11.8 W. R. Klein and B. D. Cook, 1967, "Unified Approach to Ultrasonic Light Diffraction,"
           IEEE Trans. Sonics Ultrason., SU-14, 723-733.
       11.9 H. Kogelnik, 1969, "Coupled Wave Theory for Thick Hologram Gratings," Bell Sys. Tech.
           J., 48, 2909-2947.
       11.10 A. Korpel and T.-C. Poon, 1980, "Explicit Formalism for Acousto-optic Multiple Pane-
           Wave Scattering," J. Opt. Soc. Am., 70, 817-820.
       11.11 A. Korpel, Acousto-optics, Marcel Dekker, Inc., 1988.
       11.12 R. A. Appel and M. G. Somekh, 1993, "Series Solution for Two-Frequency Bragg Interaction
           Using the Korpel-Poon Multiple-Scattering Method," J. Opt. Soc. Am. A, 10, 466 476.
       11.13 P. Phariseau, 1956, "On the Diffraction of Light by Progressive Supersonic Waves." Proc.
           Indian Acad. Sci. Sect., A 44, 165-170.
       11.14 M. R. Chatterjee, T.-C. Poon, and D. N. Sitter, 3990, "Transfer Function Formalism for
           Strong Acousto-optic Bragg Diffraction of Light Beams with Arbitrary Profiles," Acustica,
           71, 81-92.
       11.15 T.-C. Poon, M. D. McNeill, and D. J. Moore, 1997, "Modern Optical Signal Processing
           Experiments Demonstrating Intensity and Pulse-Width Modulation Using Acousto-optic
           Modulator," American Journal of Physics, 65, 917-925.