光谱学与光谱分析 |
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Laser Speckle Suppression Due to Dynamic Multiple Scattering Scheme Introduced by Oblique Incidence |
XU Mei-fang1, 2, GAO Wen-hong1, SHI Yun-bo1, WANG Hao-quan2, DU Bin-bin1 |
1. Key Laboratory of Instrumentation Science & Dynamic Measurement, Ministry of Education, North University of China, Taiyuan 030051, China 2. School of Information and Communication Engineering, North University of China, Taiyuan 030032, China |
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Abstract Speckle suppression has been the research focus in laser display technology. In the present paper, the relation between multiple scattering and the size of speckle grains is established by analyzing the properties of speckle generated by the laser beam through SiO2 suspension. Combined with dynamic light scattering theory, laser speckle suppression due to dynamic multiple scattering scheme introduced by oblique incidence is proposed. A speckle suppression element consists of a static diffuser and a light pipe containing the water suspension of SiO2 microspheres with a diameter of 300 nm and a molar concentration of 3.0×10-4 μm-3, which is integrated with the laser display system. The laser beam with different incident angles into the SiO2 suspension affecting the contrast of the speckle images is analyzed by the experiments. The results demonstrate that the contrast of the speckle image can be reduced to 0.067 from 0.43 when the beam with the incident angle of approximately 8° illuminates into the SiO2 suspension. The spatial average of speckle granules and the temporal average of speckle images were achieved by the proposed method, which improved the effect of speckle suppression. The proposed element for speckle suppression improved the reliability and reduced the cost of laser projection system, since no mechanical vibration is needed and it is convenient to integrate the element with the existing projection system.
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Received: 2013-10-15
Accepted: 2014-02-04
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Corresponding Authors:
XU Mei-fang
E-mail: xmf0129@nuc.edu.cn
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[1] Dainty J C. Opt. Acta, 1970, 17: 761. [2] Ohtsubo J,Asakura T. Opt. Lett., 1977, 1:98. [3] Silvano Donati,Giuseppe Martini. JOSA, 1979, 69(12): 1690. [4] Tiziani H J. New York: Academic Press, Inc., 1978. 5. [5] Goodman J W. Englewood: Roberts and Company Pulishers, 2007. 23. [6] Lowenthal S,Joyeux D. J. Opt. Soc. Am., 1971, 61:847. [7] Vlker A, Zakharov P, Weber B,et al. Opt. Expr., 2005, 13(24): 9782-7. [8] Kuratomi Y, Sekiya K, Satoh H,et al. J. Opt. Soc. Am. A.,2010, 27(8): 1812-7. [9] Seungdo A, Anatoliy L, Victor Y,et al. Opt. Expr.,2009, 17(1): 92. [10] Dalip S M, Dinesh N Naik, Rakesh K S,et al. Appl. Opt., 2012, 51(12): 1894. [11] Sung C S, Sin S Y, Sang Y L,et al. Displays, 2006, 27: 91. [12] Po-Hung Y, Chieh-Hui C, Cheng-Huan C. Opt. Expr.,2012, 20(15): 16552. [13] Bashkansky M, Reintjes J. Opt. Lett., 2000, 25(4): 545. [14] Akram M N, Tong Z, Ouyang G,et al. Appl. Opt.,2010, 49(17): 3297. [15] Li H, Yue Z, L Wei-qi. Laser & Infrared, 2006, 36(10): 927. [16] Falko R, Georg B, Uli L. Appl. Opt., 2009,48(19):3742. [17] Goodman J. New York: John Wiley & Sons, 2000. 207. [18] Lemieux P A,Durian D J. JOSA A, 1999, 16(7): 1651. [19] Meifang X, Yunbo S, Guoxian T,et al. International Journal of Engineering and Physical Sciences,2012, 63: 233. |
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