实用化激光电视中的共性技术研究
|
摘要
近年来人们对视频显示的画面要求不断提高,不仅追求画面的细腻,更为追求画面的艳丽,这就要求显示设备能呈现色彩更为丰富的图像,为了能让显示设备展现更多更饱和的色彩,广色域显示成为了未来一个重要的发展方向。激光显示技术作为新一代的显示技术,具有其它显示方式无法比拟的显著优点:色域宽广、颜色饱和度高、寿命长、无有害电磁射线辐射等。因此,激光显示技术受到了越来越多的关注。各种大屏幕激光电视、投影机等产品又如雨后春笋般蓬勃的发展起来,在2013年举办的全球规模最大的电子消费展CES(ConsumerElectronics Show)展会上,激光显示相关设备获得了“未来产品奖”,这也标志着激光显示作为“第四代显示技术”已经迈出了关键的一步。
然而,激光电视的这些特殊的优势恰恰带来了一些问题,如图像散斑现象严重、色彩失真、激光器体积大、散热不好等。只有解决了这些问题,才能使激光电视将其特有的优点呈现出来,具有实际应用的价值。
论文对激光显示中的共性技术进行了深入的研究。分析了散斑的产生原因,对几种抑制散斑的方法进行了对比,并提出了“随机微透镜阵列扰动”的方式抑制散斑,从理论上分析了此方法的可行性,同时在光学系统中加入了转动工程漫射体的结构,对屏幕上的散斑进行了测量,可将散斑对比度降低到1.15%,使人眼分辨不出激光散斑,极大程度的提升了激光电视的观看效果。并与以往的方法进行了对比,从而证明了此种方法的优越性。
采用更小体积的半导体激光器和全固态激光器结合,利用光纤耦合技术将这13个激光器发出的激光最后转为一条光纤输出,形成16.1W的白光,作为激光电视的激光光源,并与激光电视主体整合,实现了激光电视的小型化。针对激光电视的尺寸和所采用的爱普生型号为L3C09W-85G00的LCD面板,对投影光学系统进行了设计,在保证成像质量的前提下可以实现1080P的高清视频输出。
根据色度学理论,计算出激光电视色域与普通NTSC色域之间的转换矩阵,建立了“色域复现”的转换模型,并通过DSP和FPGA实现了高清实时“色域复现”,同时支持常见的视频输入接口。为激光电视在输入普通视频信号时与普通电视显示相同的色彩提供了解决方案。
对激光电视样机抑制散斑效果、色域复现误差、对比度和亮度均匀性进行了测试,验证了激光电视在抑制散斑、色域复现的能力,同时证明了激光电视的实用性。
In recent years, the demands of people on the visual, the pursuit of a morecolorful picture are increasing, which requires the display device can render richercolor images. In order to allow the display device to show more saturated and morecolors, the wide color gamut displays has become an important direction ofdevelopment. Laser display technology as the next generation of display technologyhas significant and incomparable advantages over other displays: wide color gamut,high color saturation, no harmful radiation and other electromagnetic radiation.Therefore, the laser display technology has been paid more and more attention. Bigscreen TV, projector and other laser products have sprung up again. In the world'slargest consumer electronics show CES (Consumer Electronics Show) exhibition in2013, laser display related equipment received a " future product award ", it alsomarks the laser display as a " fourth-generation display technology " has taken acrucial step.
In another hand, these special advantages of laser TV also bring some problems,such as image speckle phenomenon, color distortion, high volume laser, low heatdissipation and so on. Only by resolving these problems, the unique advantages oflaser TV and the value of practical application will be presented.
The common laser display technologies has been the object of intensive study inthis paper. The cause of laser speckle has been analyzed, several methods of laserspeckle reduction were compared, and proposed a way to reduce laser speckle using rotating Engineered Diffusers. This paper theoretically analyzed the feasibility of thisapproach. While the rotating Engineered Diffusers is uploaded in the optical system,the laser speckles on the screen were measured, the speckle contrast may be reducedto1.15%, people’s eyes can not tell the laser speckles which greatly enhance theviewing level laser TV. Compared with the conventional method, this method of therotating Engineered Diffusers is more efficient.
A smaller volume of semiconductor lasers and solid-state lasers are used andcombined these13lasers into one fiber using fiber-coupled technology. This finalfiber emits16.1W “white” laser which is the laser light source of laser TV. And thelight source is integrated in the main laser TV, so that we can achieve theminiaturization of laser TV. Consider the size of the laser TV and LCD panel(EpsonL3C09W-85G00), the projection optical system has been designed to ensure the highimage quality so that the laser TV can achieve1080P HD video output.
According to the chromaticity theory, the transformation matrix between lasertelevision gamut and ordinary NTSC color gamut is calculated, a "gamut recurrence"conversion model is established and realized by DSP and FPGA HD real-time "gamut recurrence". The laser TV also supports common video input interface.Provide a solution that laser TV can show the original NTSC gamut when theordinary television video signal is input.
Speckles contrast, the gamut recurrence error, contrast and brightnesshomogeneity of laser TV are measured to verify the abilities of laser speckle reductionand color gamut recurrence, and proves the practical value of laser television.
然而,激光电视的这些特殊的优势恰恰带来了一些问题,如图像散斑现象严重、色彩失真、激光器体积大、散热不好等。只有解决了这些问题,才能使激光电视将其特有的优点呈现出来,具有实际应用的价值。
论文对激光显示中的共性技术进行了深入的研究。分析了散斑的产生原因,对几种抑制散斑的方法进行了对比,并提出了“随机微透镜阵列扰动”的方式抑制散斑,从理论上分析了此方法的可行性,同时在光学系统中加入了转动工程漫射体的结构,对屏幕上的散斑进行了测量,可将散斑对比度降低到1.15%,使人眼分辨不出激光散斑,极大程度的提升了激光电视的观看效果。并与以往的方法进行了对比,从而证明了此种方法的优越性。
采用更小体积的半导体激光器和全固态激光器结合,利用光纤耦合技术将这13个激光器发出的激光最后转为一条光纤输出,形成16.1W的白光,作为激光电视的激光光源,并与激光电视主体整合,实现了激光电视的小型化。针对激光电视的尺寸和所采用的爱普生型号为L3C09W-85G00的LCD面板,对投影光学系统进行了设计,在保证成像质量的前提下可以实现1080P的高清视频输出。
根据色度学理论,计算出激光电视色域与普通NTSC色域之间的转换矩阵,建立了“色域复现”的转换模型,并通过DSP和FPGA实现了高清实时“色域复现”,同时支持常见的视频输入接口。为激光电视在输入普通视频信号时与普通电视显示相同的色彩提供了解决方案。
对激光电视样机抑制散斑效果、色域复现误差、对比度和亮度均匀性进行了测试,验证了激光电视在抑制散斑、色域复现的能力,同时证明了激光电视的实用性。
In recent years, the demands of people on the visual, the pursuit of a morecolorful picture are increasing, which requires the display device can render richercolor images. In order to allow the display device to show more saturated and morecolors, the wide color gamut displays has become an important direction ofdevelopment. Laser display technology as the next generation of display technologyhas significant and incomparable advantages over other displays: wide color gamut,high color saturation, no harmful radiation and other electromagnetic radiation.Therefore, the laser display technology has been paid more and more attention. Bigscreen TV, projector and other laser products have sprung up again. In the world'slargest consumer electronics show CES (Consumer Electronics Show) exhibition in2013, laser display related equipment received a " future product award ", it alsomarks the laser display as a " fourth-generation display technology " has taken acrucial step.
In another hand, these special advantages of laser TV also bring some problems,such as image speckle phenomenon, color distortion, high volume laser, low heatdissipation and so on. Only by resolving these problems, the unique advantages oflaser TV and the value of practical application will be presented.
The common laser display technologies has been the object of intensive study inthis paper. The cause of laser speckle has been analyzed, several methods of laserspeckle reduction were compared, and proposed a way to reduce laser speckle using rotating Engineered Diffusers. This paper theoretically analyzed the feasibility of thisapproach. While the rotating Engineered Diffusers is uploaded in the optical system,the laser speckles on the screen were measured, the speckle contrast may be reducedto1.15%, people’s eyes can not tell the laser speckles which greatly enhance theviewing level laser TV. Compared with the conventional method, this method of therotating Engineered Diffusers is more efficient.
A smaller volume of semiconductor lasers and solid-state lasers are used andcombined these13lasers into one fiber using fiber-coupled technology. This finalfiber emits16.1W “white” laser which is the laser light source of laser TV. And thelight source is integrated in the main laser TV, so that we can achieve theminiaturization of laser TV. Consider the size of the laser TV and LCD panel(EpsonL3C09W-85G00), the projection optical system has been designed to ensure the highimage quality so that the laser TV can achieve1080P HD video output.
According to the chromaticity theory, the transformation matrix between lasertelevision gamut and ordinary NTSC color gamut is calculated, a "gamut recurrence"conversion model is established and realized by DSP and FPGA HD real-time "gamut recurrence". The laser TV also supports common video input interface.Provide a solution that laser TV can show the original NTSC gamut when theordinary television video signal is input.
Speckles contrast, the gamut recurrence error, contrast and brightnesshomogeneity of laser TV are measured to verify the abilities of laser speckle reductionand color gamut recurrence, and proves the practical value of laser television.
引文
[1]李玉翔,姚建铨,蔡彬晶,等.激光电视的研究进展及趋势分析[J].激光杂志,2007,28(1):1-2.
[2]王延伟,毕勇,王斌,等.大屏幕激光投影与激光电视[J].物理,2010,39(04):232-237.
[3]徐济仁,陈家松,牛纪海.激光电视技术与发展[J].电视工程,2003(3):7-9.
[4]许祖彦.激光显示——新一代显示技术[J].激光与红外,2006,36(B09):737-741.
[5] Sugiura H, Kuwata M, Inoue Y, et al.3.4: Invited Paper: Laser TV‐Ultra WideColor Gamut in Conformity with xvYCC[C]//SID Symposium Digest ofTechnical Papers. Blackwell Publishing Ltd,2007,38(1):12-15.
[6] Nebolsine P E, Pirri A N. Laser propulsion: the early years[C]//BEAMEDENERGY PROPULSION: First International Symposium on Beamed EnergyPropulsion.AIP Publishing,2003,664(1):11-21.
[7]陈旭,冯玉涛,刘伟奇,等.大屏背投激光显示广角镜头的设计[J].光学精密工程,2011,19(5):945-950.
[8]屈伟平.激光显示技术掀起色彩革命[J].有线电视技术,2010(2):76-78.
[9]翟强.中国激光显示产业平台综述[J].物理,2010,39(04):238-242.
[10]王延伟,毕勇,王斌,等.大屏幕激光投影与激光电视[J].物理,2010,39(04):232-237.
[11]冯传岗.谈谈激光电视[J].卫星电视与宽带多媒体,2011,8:41-45.
[12]姚爱云,侯玮,林学春.全固态三基色激光大屏幕投影显示实验[J].物理,2004,33(02):0.
[13]赵富宝,武怀玉,杨延宁.浅议激光显示技术及其进展[J].现代显示,2013(1):27-30.
[14]吴少凡.我国激光显示产业发展战略研究[J].2010.
[15]胡居广.大屏幕真彩色全固态激光显示系统关键技术研究[D].天津大学,2004.
[16]李立山.采用激光显示技术的背投拼接墙技术介绍[J].中国多媒体通信,2012(10):70-71.
[17]柴燕,毕勇,颜博霞,等.全球激光显示技术专利分布格局与态势分析[J].液晶与显示,2011,26(3):329.
[18]赵汉鼎.投影式激光显示产业化配套现状与展望[J].电视技术,2013,37(4):10-12.
[19]马红丽.自主创新推进激光显示产业发展[J].中国科技投资,2008(1):53-54.
[20]陆涣.惊艳的激光显示[J].科学大众.中学生,2010(7):12-13.
[21]毕勇,许祖彦,房涛,等.大屏幕全固态激光全色显示系统题目[J].中国光学学会2006年学术大会论文摘要集,2006.
[22]李光晓.激光显示技术的新进展[J].光电子技术与信息,1997,10(2):28-30.
[23]翟强.激光显示:下一代的显示技术[J].中国科技投资,2008(1):54-55.
[24]代安娜,王彤.激光技术的全新视觉感受[J].科技创新与品牌,2012(5).
[25]彭国贤.激光在显示技术中的应用[J].自然杂志,1983,5:010.
[26]一流.明日之星:激光电视[J].实用影音技术,2008(8):8-8.
[27]冯传岗.激光电视:21世纪电视机市场中最强的竞争者[J].有线电视技术,2011(3):83-86.
[28]李乐.半导体激光与现代显示[J].现代显示,1995,2:22-24.
[29]Hecht J. Short history of laser development[J]. Optical Engineering,2010,49(9):091002-091002-23.
[30]王路威.半导体激光器的发展及其应用[J].成都大学学报:自然科学版,2003,22(3):34-38.
[31]郑权,陈颖新.全固态激光器产业发展的趋势[J].光机电信息,2001(12):17-20.
[32]楼棋洪.准分子激光器的发展和应用[J][J].中国激光,1994,21(5):361-364.
[33]陈辉,高红,张云刚,等.半导体激光器的发展及其在激光光谱学中的应用[J].哈尔滨师范大学自然科学学报,2005,21(1):40-43.
[34]李修乾,洪延姬.高能固体激光器现状及发展趋势[J].装备指挥技术学院学报,2004,15(1):101-105.
[35]李学千.半导体激光器的最新进展及其应用[J].长春光学精密机械学院学报,1997,20(4):56-63.
[36]余永林.半导体激光器的发展[J].激光与光电子学进展,2007,44(2):69-72.
[37]王德,李学千.半导体激光器的最新进展及其应用现状[J].光学精密工程,2001,3.
[38]杜秀兰,吴峰.固体激光器的灯泵浦和二极管泵浦方式比较[J].应用光学,2004,25(3):37-40.
[39]周城,叶子青,郑权,等.半导体泵浦全固体蓝光激光器的研究进展[J].光学精密工程,2002,10(3).
[40]王启明.中国半导体激光器的历次突破与发展(邀请论文)[J].中国激光,2010,9:006.
[41]赵星,方志良,崔继承,等.微型投影机光学引擎的研究[J].光学学报,2007,27(5):913-918.
[42]王蔚生,邱菘,毛敏,等.采用LED光源DLP背投电视光学引擎的研究[J].现代显示,2007(12):22-25.
[43]Seime L, Hardeberg J Y. Characterisation of LCD and DLP projectiondisplays[C]//Color and Imaging Conference. Society for Imaging Science andTechnology,2002,2002(1):277-282.
[44]沈华,何勇,朱日宏. LCD投影系统光学引擎的计算机仿真分析[J].应用光学,2007,28(2):181-186.
[45]徐佳.基于LED的DLP投影显示光学引擎研究[D].华东师范大学硕士学位论文,2008.
[46]张增宝.投影显示系统光学引擎研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2004.
[47]Powell E. The Great Technology War: LCD vs. DLP[J]. Kommentaari ProjectorCentral sivustolla. Haettu,2004,10:2005.
[48]邱崧,王蔚生,王淑仙,等.基于LED光源的DLP光学引擎的光学设计(英文)[J].电子器件,2008,6:001.
[49]顾建锋.液晶光阀光学引擎分色合色设计与仿真[D].南京理工大学,2003.
[50]付振平.高清晰度液晶背投影光学引擎[J].家庭电子,2003(2):16-16.
[51]何勇,朱日宏.应用光学2007,28(2)181-186DOI: ISSN:1002-2082CN:61-1171/O4[J].
[52]吴业权. DIY投影机高效光学引擎初探[J].电子制作,2003,8:034.
[53]Kahn F J. Projection display technologies for the new millennium[C]//ElectronicImaging. International Society for Optics and Photonics,2000:12-18.
[54]沈铮.液晶光阀[J].光电子技术,1983,2:010.
[55]田志辉,刘伟奇,冯睿,等.基于DLP投影方式的激光显示系统[J].液晶与显示,2007,22(3).
[56]张新,张增宝,翁志成,等.用于投影显示的SCR色轮系统设计[J].大珩先生九十华诞文集暨中国光学学会2004年学术大会论文集,2004.
[57]董磊.激光三维显示中散斑抑制及散斑测量[D].中国科学技术大学,2013.
[58]康玉思,刘伟奇,冯睿,等.激光电视的消干涉[J].中国激光,2009,35(4):615-619.
[59]李霞,康玉思.激光显示中散斑噪声的抑制[J].应用光学,2010,31(4):648.
[60]贾琼瑶,贺锋涛.激光投影显示中散斑均化问题的研究[J].激光技术,2013,37(3):400-403.
[61]孙鸣捷.微型投影显示系统中混合光源照明技术和激光散斑消除技术的研究
[D].浙江大学,2010.
[62]王应宗.激光散斑的产生机理,统计性质及减弱方法[J].应用光学,1983,4:006.
[63]常宏.激光显示中散斑抑制和主观散斑跟踪的研究[D].中国科学技术大学,2010.
[64]黄伟.激光散斑跟踪和激光扫描显示中散斑机理的研究[D].中国科学技术大学,2008.
[65]张岳,郝丽,柳华,等.激光显示的原理与实现[J].光学精密工程,2006,14(3):402.
[66]田志辉,刘伟奇,李霞,等.激光显示中散斑的减弱[J].光学精密工程,2007,15(9):1366.
[67]李霞,郝丽,刘伟奇,等.激光显示中散斑减弱的研究[J].液晶与显示,2007,22(3):320-324.
[68]李霞,刘伟奇,田志辉,等.激光显示中散斑对比度的降低[J].液晶与显示,2008,23(2):153-156.
[69]郝丽,张岳,刘伟奇,等.激光显示中散斑的抑制[J].激光与红外,2006,36(10):927-930.
[70]郝丽,张岳,刘伟奇,等.激光显示中斑纹横向尺寸的估计[J].液晶与显示,2006,21(3):241-245.
[71]Seime L, Hardeberg J Y. Colorimetric characterization of LCD and DLPprojection displays[J]. Journal of the Society for Information Display,2003,11(2):349-358.
[72]Goodman J W. Speckle phenomena in optics: theory and applications[M].Roberts and Company Publishers,2007.
[73]伍小平,何世平,李志超.空间散斑的运动规律[J].物理学报,2005,29(9):1142-1150.
[74]Fran on M. Laser speckle and applications in optics[M]. Elsevier,2012.
[75]Baribeau R, Rioux M. Influence of speckle on laser range finders[J]. AppliedOptics,1991,30(20):2873-2878.
[76]田志辉,刘伟奇,柳华,等.激光显示中的色域转换系统[J].液晶与显示,2007,22(4):423-427.
[77]张继艳.激光显示颜色系统的建模与校正[D].中国科学院研究生院(长春光学精密机械与物理研究所),2006.
[78]Cok R S, Feldman R D, Burtis J C. Broad color gamut display: U.S. Patent6,570,584[P].2003-5-27.
[79]Ng Y S. Input scanner color mapping and input/output color gamuttransformation: U.S. Patent5,185,661[P].1993-2-9.
[80]Morovi J. Color gamut mapping[M]. John Wiley&Sons,2008.
[81]Hung P C, Berns R S. Determination of constant hue loci for a CRT gamut andtheir predictions using color appearance spaces[J]. Color Research&Application,1995,20(5):285-295.
[82]Balasubramanian R, Dalal E. Method for quantifying the color gamut of anoutput device[C]//Electronic Imaging'97. International Society for Optics andPhotonics,1997:110-116.
[83]McCarthy A L, Spaulding K E, Giorgianni E J. Representing an extended colorgamut digital image in a limited color gamut color space: U.S. Patent6,335,983[P].2002-1-1.
[84]陈旭,刘伟奇,魏忠伦,等.激光显示中匀色坐标系的建立与色差分析[J].液晶与显示,2008,23(4):427-431.
[85]张继艳,刘伟奇,魏忠伦,等.基于激光显示的颜色系统的建立[J].液晶与显示,2006,21(1):34-37.
[86]Wallace G, Chen H, Li K. Color gamut matching for tiled displaywalls[C]//Proceedings of the workshop on Virtual environments2003. ACM,2003:293-302.
[87]陆琼.激光显示系统的设计与实现[J].艺术科技,2001(3):8-11.
[88]赵新亮,林妩媚,曹益平,等.激光显示中声光调制器的非线性实时校正[J].光电工程,2005,32(4):66-69.
[89]李义辉.激光显示的色域扩展研究[D].山东大学,2012.
[90]魏忠伦.基于激光显示的颜色复现的研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2004.
[91]张念伍.基于激光显示系统的跨设备色彩传输研究[D].山东大学,2012.
[92]邱天星.激光显示系统色彩管理方法研究[D].山东大学,2010.
[93]陈宇,丁铁夫.显示量化误差对色域转换的影响[J].发光学报,2004,25(1):98-102.
[94]刘英.基于激光电视的色域扩展映射研究[D].山东大学,2011.
[95]李琦. RGB-LED背光液晶显示器的色域映射算法研究[D].山东大学,2009.
[96]田广,黄天,余松煜.色域变换及具体实现[J].电视技术,1998,6.
[97]Smith A R. Color gamut transform pairs[C]//ACM Siggraph Computer Graphics.ACM,1978,12(3):12-19.
[98]黄慧娟.激光电视中视频信号的编码与解码应用研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2005.
[99]陈宇,丁铁夫,辛华,等.显示色域转换的误差影响效应[J].液晶与显示,2003,18(5):351-356.
[100]孟凡亚. CIECAM02均匀性和色域映射算法研究[D][D].南京:南京林业大学研究生硕士学位论文,2009.
[101]史瑞芝,曹朝辉,任晓波,等.基于色空间转换与色域映射的跨媒体颜色传输[J].测绘科学技术学报,2008,25(2):79-82.
[102]郝丽,刘伟奇,张岳,等.激光显示中颜色系统的校正[J].微计算机信息,2007(03Z):159-161.
[103]朱俊.小型激光布景系统的研究[D].长春理工大学,2008.
[104]刘红.激光显示消散斑技术与三片式LCOS激光投影系统的研究与实现[D].华东师范大学,2012.
[105]邱建军,张红艳,骆卫华,等.像面散斑平均尺寸对激光散斑成像的影响[J].光学学报,2009(7):1863-1867.
[106]龚浩瀚,刘诚.激光散斑相关性和位移的关系研究[J].光学学报,2001,21(2):211-214.
[107]李林涛,郭霏,尹娜,等.激光散斑特性的实验研究[J].长春理工大学学报,2008,31(1):85-88.
[108]武颖丽.粗糙目标激光散斑统计特性及其微运动检测[D].西安电子科技大学,2013.
[109]张耿.粗糙目标激光散斑统计特性及微运动特征分析[D].西安电子科技大学,2013.
[110] Dainty J C. Laser speckle and related phenomena[C]//Berlin and New York,Springer-Verlag (Topics inApplied Physics. Volume9),1975.298p.1975,9.
[111] Goodman J W. Statistical properties of laser speckle patterns[M]//Laserspeckle and related phenomena. Springer Berlin Heidelberg,1975:9-75.
[112] Briers J D, Webster S. Laser speckle contrast analysis (LASCA): anonscanning, full-field technique for monitoring capillary blood flow[J]. Journalof biomedical optics,1996,1(2):174-179.
[113] Yamaguchi I. A laser-speckle strain gauge[J]. Journal of Physics E: ScientificInstruments,1981,14(11):1270.
[114] Dudderar T D, Simpkins P G. Laser speckle photography in a fluidmedium[J]. Nature,1977,270(5632):45-47.
[115] Wang L, Tschudi T, Halldorsson T, et al. Speckle reduction in laser projectionsystems by diffractive optical elements[J]. Applied Optics,1998,37(10):1770-1775.
[116] Tamaki Y, Araie M, Kawamoto E, et al. Non-contact, two-dimensionalmeasurement of tissue circulation in choroid and optic nerve head using laserspeckle phenomenon[J]. Experimental eye research,1995,60(4):373-383.
[117]冯能云.激光散斑信号处理方法研究[D].华中科技大学,2012.
[118]王之江,顾培森.实用光学技术手册[M].北京:机械工业出版社,2007.343-350
[119]张以谟.应用光学[M].北京:机械工业出版社,1988:401-402、166-167
[120]郁道银,谈恒英.工程光学[M].北京:机械工业出版社,2002,68-69
[121]王之江,光学技术手册(下册).第一版.北京:机械工业出版社.1994,440-450
[122]荆其诚,焦书兰,喻柏林.色度学[M].科学出版社,1979,19(79):238.
[123]色度学[M].北京理工大学出版社,1990.
[124]韩秋蕾,刘伟奇,朱明.基于TMS320C6416的色域扩展方法[J].微计算机信息,2007(02Z):169-170.
[125]姜浩.色域扩展算法研究及硬件实现[D].,2007.
[126]韩秋蕾,刘伟奇,姚志军,等.一种基于TMS320C6416T的激光色域转换方法[J].电子器件,2007,30(3):976-979.
[127]徐文超,于意仲,柴耀龙,等.基于Virtex-5FPGA的激光电视色域变换算法的实现[J].天津职业技术师范大学学报,2012,21(4):30-33.
[128]周金芳,刘旭.背投系统视角计算方法研究[J].光子学报,2007,36(9):1718-1721.
[129]张海宏.微型球面结构光学型背投屏幕的光学原理及特点——关于三枪屏与LCD屏的区别[J].电子制作,2003(007):62-64.
[130]田有良,王慧,陈昱,等.激光投影显示中散斑的测量[J].现代显示,2012(4):34-37.
[131]邱亚峰,常本康,孙恋君,高有堂等.像增强器的荧光屏亮度均匀性测试的校正法研究[J].光学技术,2008,34(6):911-913
[132]丁毅,顾培夫,实现均匀照明的自由曲面反射器[J].光学学报,2007,27(3):540-544
[133]杜温锡.均匀照明和照度分布计算[J].光学机械,1978,(4):1-4
[134]田园.CCD图像对比度测试方法研究[D]:[硕士学位论文].吉林:长春理工大学
[135]朱小清等.光度测量技术及仪器,北京:中国计量出版社,1992,128-148
[2]王延伟,毕勇,王斌,等.大屏幕激光投影与激光电视[J].物理,2010,39(04):232-237.
[3]徐济仁,陈家松,牛纪海.激光电视技术与发展[J].电视工程,2003(3):7-9.
[4]许祖彦.激光显示——新一代显示技术[J].激光与红外,2006,36(B09):737-741.
[5] Sugiura H, Kuwata M, Inoue Y, et al.3.4: Invited Paper: Laser TV‐Ultra WideColor Gamut in Conformity with xvYCC[C]//SID Symposium Digest ofTechnical Papers. Blackwell Publishing Ltd,2007,38(1):12-15.
[6] Nebolsine P E, Pirri A N. Laser propulsion: the early years[C]//BEAMEDENERGY PROPULSION: First International Symposium on Beamed EnergyPropulsion.AIP Publishing,2003,664(1):11-21.
[7]陈旭,冯玉涛,刘伟奇,等.大屏背投激光显示广角镜头的设计[J].光学精密工程,2011,19(5):945-950.
[8]屈伟平.激光显示技术掀起色彩革命[J].有线电视技术,2010(2):76-78.
[9]翟强.中国激光显示产业平台综述[J].物理,2010,39(04):238-242.
[10]王延伟,毕勇,王斌,等.大屏幕激光投影与激光电视[J].物理,2010,39(04):232-237.
[11]冯传岗.谈谈激光电视[J].卫星电视与宽带多媒体,2011,8:41-45.
[12]姚爱云,侯玮,林学春.全固态三基色激光大屏幕投影显示实验[J].物理,2004,33(02):0.
[13]赵富宝,武怀玉,杨延宁.浅议激光显示技术及其进展[J].现代显示,2013(1):27-30.
[14]吴少凡.我国激光显示产业发展战略研究[J].2010.
[15]胡居广.大屏幕真彩色全固态激光显示系统关键技术研究[D].天津大学,2004.
[16]李立山.采用激光显示技术的背投拼接墙技术介绍[J].中国多媒体通信,2012(10):70-71.
[17]柴燕,毕勇,颜博霞,等.全球激光显示技术专利分布格局与态势分析[J].液晶与显示,2011,26(3):329.
[18]赵汉鼎.投影式激光显示产业化配套现状与展望[J].电视技术,2013,37(4):10-12.
[19]马红丽.自主创新推进激光显示产业发展[J].中国科技投资,2008(1):53-54.
[20]陆涣.惊艳的激光显示[J].科学大众.中学生,2010(7):12-13.
[21]毕勇,许祖彦,房涛,等.大屏幕全固态激光全色显示系统题目[J].中国光学学会2006年学术大会论文摘要集,2006.
[22]李光晓.激光显示技术的新进展[J].光电子技术与信息,1997,10(2):28-30.
[23]翟强.激光显示:下一代的显示技术[J].中国科技投资,2008(1):54-55.
[24]代安娜,王彤.激光技术的全新视觉感受[J].科技创新与品牌,2012(5).
[25]彭国贤.激光在显示技术中的应用[J].自然杂志,1983,5:010.
[26]一流.明日之星:激光电视[J].实用影音技术,2008(8):8-8.
[27]冯传岗.激光电视:21世纪电视机市场中最强的竞争者[J].有线电视技术,2011(3):83-86.
[28]李乐.半导体激光与现代显示[J].现代显示,1995,2:22-24.
[29]Hecht J. Short history of laser development[J]. Optical Engineering,2010,49(9):091002-091002-23.
[30]王路威.半导体激光器的发展及其应用[J].成都大学学报:自然科学版,2003,22(3):34-38.
[31]郑权,陈颖新.全固态激光器产业发展的趋势[J].光机电信息,2001(12):17-20.
[32]楼棋洪.准分子激光器的发展和应用[J][J].中国激光,1994,21(5):361-364.
[33]陈辉,高红,张云刚,等.半导体激光器的发展及其在激光光谱学中的应用[J].哈尔滨师范大学自然科学学报,2005,21(1):40-43.
[34]李修乾,洪延姬.高能固体激光器现状及发展趋势[J].装备指挥技术学院学报,2004,15(1):101-105.
[35]李学千.半导体激光器的最新进展及其应用[J].长春光学精密机械学院学报,1997,20(4):56-63.
[36]余永林.半导体激光器的发展[J].激光与光电子学进展,2007,44(2):69-72.
[37]王德,李学千.半导体激光器的最新进展及其应用现状[J].光学精密工程,2001,3.
[38]杜秀兰,吴峰.固体激光器的灯泵浦和二极管泵浦方式比较[J].应用光学,2004,25(3):37-40.
[39]周城,叶子青,郑权,等.半导体泵浦全固体蓝光激光器的研究进展[J].光学精密工程,2002,10(3).
[40]王启明.中国半导体激光器的历次突破与发展(邀请论文)[J].中国激光,2010,9:006.
[41]赵星,方志良,崔继承,等.微型投影机光学引擎的研究[J].光学学报,2007,27(5):913-918.
[42]王蔚生,邱菘,毛敏,等.采用LED光源DLP背投电视光学引擎的研究[J].现代显示,2007(12):22-25.
[43]Seime L, Hardeberg J Y. Characterisation of LCD and DLP projectiondisplays[C]//Color and Imaging Conference. Society for Imaging Science andTechnology,2002,2002(1):277-282.
[44]沈华,何勇,朱日宏. LCD投影系统光学引擎的计算机仿真分析[J].应用光学,2007,28(2):181-186.
[45]徐佳.基于LED的DLP投影显示光学引擎研究[D].华东师范大学硕士学位论文,2008.
[46]张增宝.投影显示系统光学引擎研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2004.
[47]Powell E. The Great Technology War: LCD vs. DLP[J]. Kommentaari ProjectorCentral sivustolla. Haettu,2004,10:2005.
[48]邱崧,王蔚生,王淑仙,等.基于LED光源的DLP光学引擎的光学设计(英文)[J].电子器件,2008,6:001.
[49]顾建锋.液晶光阀光学引擎分色合色设计与仿真[D].南京理工大学,2003.
[50]付振平.高清晰度液晶背投影光学引擎[J].家庭电子,2003(2):16-16.
[51]何勇,朱日宏.应用光学2007,28(2)181-186DOI: ISSN:1002-2082CN:61-1171/O4[J].
[52]吴业权. DIY投影机高效光学引擎初探[J].电子制作,2003,8:034.
[53]Kahn F J. Projection display technologies for the new millennium[C]//ElectronicImaging. International Society for Optics and Photonics,2000:12-18.
[54]沈铮.液晶光阀[J].光电子技术,1983,2:010.
[55]田志辉,刘伟奇,冯睿,等.基于DLP投影方式的激光显示系统[J].液晶与显示,2007,22(3).
[56]张新,张增宝,翁志成,等.用于投影显示的SCR色轮系统设计[J].大珩先生九十华诞文集暨中国光学学会2004年学术大会论文集,2004.
[57]董磊.激光三维显示中散斑抑制及散斑测量[D].中国科学技术大学,2013.
[58]康玉思,刘伟奇,冯睿,等.激光电视的消干涉[J].中国激光,2009,35(4):615-619.
[59]李霞,康玉思.激光显示中散斑噪声的抑制[J].应用光学,2010,31(4):648.
[60]贾琼瑶,贺锋涛.激光投影显示中散斑均化问题的研究[J].激光技术,2013,37(3):400-403.
[61]孙鸣捷.微型投影显示系统中混合光源照明技术和激光散斑消除技术的研究
[D].浙江大学,2010.
[62]王应宗.激光散斑的产生机理,统计性质及减弱方法[J].应用光学,1983,4:006.
[63]常宏.激光显示中散斑抑制和主观散斑跟踪的研究[D].中国科学技术大学,2010.
[64]黄伟.激光散斑跟踪和激光扫描显示中散斑机理的研究[D].中国科学技术大学,2008.
[65]张岳,郝丽,柳华,等.激光显示的原理与实现[J].光学精密工程,2006,14(3):402.
[66]田志辉,刘伟奇,李霞,等.激光显示中散斑的减弱[J].光学精密工程,2007,15(9):1366.
[67]李霞,郝丽,刘伟奇,等.激光显示中散斑减弱的研究[J].液晶与显示,2007,22(3):320-324.
[68]李霞,刘伟奇,田志辉,等.激光显示中散斑对比度的降低[J].液晶与显示,2008,23(2):153-156.
[69]郝丽,张岳,刘伟奇,等.激光显示中散斑的抑制[J].激光与红外,2006,36(10):927-930.
[70]郝丽,张岳,刘伟奇,等.激光显示中斑纹横向尺寸的估计[J].液晶与显示,2006,21(3):241-245.
[71]Seime L, Hardeberg J Y. Colorimetric characterization of LCD and DLPprojection displays[J]. Journal of the Society for Information Display,2003,11(2):349-358.
[72]Goodman J W. Speckle phenomena in optics: theory and applications[M].Roberts and Company Publishers,2007.
[73]伍小平,何世平,李志超.空间散斑的运动规律[J].物理学报,2005,29(9):1142-1150.
[74]Fran on M. Laser speckle and applications in optics[M]. Elsevier,2012.
[75]Baribeau R, Rioux M. Influence of speckle on laser range finders[J]. AppliedOptics,1991,30(20):2873-2878.
[76]田志辉,刘伟奇,柳华,等.激光显示中的色域转换系统[J].液晶与显示,2007,22(4):423-427.
[77]张继艳.激光显示颜色系统的建模与校正[D].中国科学院研究生院(长春光学精密机械与物理研究所),2006.
[78]Cok R S, Feldman R D, Burtis J C. Broad color gamut display: U.S. Patent6,570,584[P].2003-5-27.
[79]Ng Y S. Input scanner color mapping and input/output color gamuttransformation: U.S. Patent5,185,661[P].1993-2-9.
[80]Morovi J. Color gamut mapping[M]. John Wiley&Sons,2008.
[81]Hung P C, Berns R S. Determination of constant hue loci for a CRT gamut andtheir predictions using color appearance spaces[J]. Color Research&Application,1995,20(5):285-295.
[82]Balasubramanian R, Dalal E. Method for quantifying the color gamut of anoutput device[C]//Electronic Imaging'97. International Society for Optics andPhotonics,1997:110-116.
[83]McCarthy A L, Spaulding K E, Giorgianni E J. Representing an extended colorgamut digital image in a limited color gamut color space: U.S. Patent6,335,983[P].2002-1-1.
[84]陈旭,刘伟奇,魏忠伦,等.激光显示中匀色坐标系的建立与色差分析[J].液晶与显示,2008,23(4):427-431.
[85]张继艳,刘伟奇,魏忠伦,等.基于激光显示的颜色系统的建立[J].液晶与显示,2006,21(1):34-37.
[86]Wallace G, Chen H, Li K. Color gamut matching for tiled displaywalls[C]//Proceedings of the workshop on Virtual environments2003. ACM,2003:293-302.
[87]陆琼.激光显示系统的设计与实现[J].艺术科技,2001(3):8-11.
[88]赵新亮,林妩媚,曹益平,等.激光显示中声光调制器的非线性实时校正[J].光电工程,2005,32(4):66-69.
[89]李义辉.激光显示的色域扩展研究[D].山东大学,2012.
[90]魏忠伦.基于激光显示的颜色复现的研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2004.
[91]张念伍.基于激光显示系统的跨设备色彩传输研究[D].山东大学,2012.
[92]邱天星.激光显示系统色彩管理方法研究[D].山东大学,2010.
[93]陈宇,丁铁夫.显示量化误差对色域转换的影响[J].发光学报,2004,25(1):98-102.
[94]刘英.基于激光电视的色域扩展映射研究[D].山东大学,2011.
[95]李琦. RGB-LED背光液晶显示器的色域映射算法研究[D].山东大学,2009.
[96]田广,黄天,余松煜.色域变换及具体实现[J].电视技术,1998,6.
[97]Smith A R. Color gamut transform pairs[C]//ACM Siggraph Computer Graphics.ACM,1978,12(3):12-19.
[98]黄慧娟.激光电视中视频信号的编码与解码应用研究[D].中国科学院研究生院(长春光学精密机械与物理研究所),2005.
[99]陈宇,丁铁夫,辛华,等.显示色域转换的误差影响效应[J].液晶与显示,2003,18(5):351-356.
[100]孟凡亚. CIECAM02均匀性和色域映射算法研究[D][D].南京:南京林业大学研究生硕士学位论文,2009.
[101]史瑞芝,曹朝辉,任晓波,等.基于色空间转换与色域映射的跨媒体颜色传输[J].测绘科学技术学报,2008,25(2):79-82.
[102]郝丽,刘伟奇,张岳,等.激光显示中颜色系统的校正[J].微计算机信息,2007(03Z):159-161.
[103]朱俊.小型激光布景系统的研究[D].长春理工大学,2008.
[104]刘红.激光显示消散斑技术与三片式LCOS激光投影系统的研究与实现[D].华东师范大学,2012.
[105]邱建军,张红艳,骆卫华,等.像面散斑平均尺寸对激光散斑成像的影响[J].光学学报,2009(7):1863-1867.
[106]龚浩瀚,刘诚.激光散斑相关性和位移的关系研究[J].光学学报,2001,21(2):211-214.
[107]李林涛,郭霏,尹娜,等.激光散斑特性的实验研究[J].长春理工大学学报,2008,31(1):85-88.
[108]武颖丽.粗糙目标激光散斑统计特性及其微运动检测[D].西安电子科技大学,2013.
[109]张耿.粗糙目标激光散斑统计特性及微运动特征分析[D].西安电子科技大学,2013.
[110] Dainty J C. Laser speckle and related phenomena[C]//Berlin and New York,Springer-Verlag (Topics inApplied Physics. Volume9),1975.298p.1975,9.
[111] Goodman J W. Statistical properties of laser speckle patterns[M]//Laserspeckle and related phenomena. Springer Berlin Heidelberg,1975:9-75.
[112] Briers J D, Webster S. Laser speckle contrast analysis (LASCA): anonscanning, full-field technique for monitoring capillary blood flow[J]. Journalof biomedical optics,1996,1(2):174-179.
[113] Yamaguchi I. A laser-speckle strain gauge[J]. Journal of Physics E: ScientificInstruments,1981,14(11):1270.
[114] Dudderar T D, Simpkins P G. Laser speckle photography in a fluidmedium[J]. Nature,1977,270(5632):45-47.
[115] Wang L, Tschudi T, Halldorsson T, et al. Speckle reduction in laser projectionsystems by diffractive optical elements[J]. Applied Optics,1998,37(10):1770-1775.
[116] Tamaki Y, Araie M, Kawamoto E, et al. Non-contact, two-dimensionalmeasurement of tissue circulation in choroid and optic nerve head using laserspeckle phenomenon[J]. Experimental eye research,1995,60(4):373-383.
[117]冯能云.激光散斑信号处理方法研究[D].华中科技大学,2012.
[118]王之江,顾培森.实用光学技术手册[M].北京:机械工业出版社,2007.343-350
[119]张以谟.应用光学[M].北京:机械工业出版社,1988:401-402、166-167
[120]郁道银,谈恒英.工程光学[M].北京:机械工业出版社,2002,68-69
[121]王之江,光学技术手册(下册).第一版.北京:机械工业出版社.1994,440-450
[122]荆其诚,焦书兰,喻柏林.色度学[M].科学出版社,1979,19(79):238.
[123]色度学[M].北京理工大学出版社,1990.
[124]韩秋蕾,刘伟奇,朱明.基于TMS320C6416的色域扩展方法[J].微计算机信息,2007(02Z):169-170.
[125]姜浩.色域扩展算法研究及硬件实现[D].,2007.
[126]韩秋蕾,刘伟奇,姚志军,等.一种基于TMS320C6416T的激光色域转换方法[J].电子器件,2007,30(3):976-979.
[127]徐文超,于意仲,柴耀龙,等.基于Virtex-5FPGA的激光电视色域变换算法的实现[J].天津职业技术师范大学学报,2012,21(4):30-33.
[128]周金芳,刘旭.背投系统视角计算方法研究[J].光子学报,2007,36(9):1718-1721.
[129]张海宏.微型球面结构光学型背投屏幕的光学原理及特点——关于三枪屏与LCD屏的区别[J].电子制作,2003(007):62-64.
[130]田有良,王慧,陈昱,等.激光投影显示中散斑的测量[J].现代显示,2012(4):34-37.
[131]邱亚峰,常本康,孙恋君,高有堂等.像增强器的荧光屏亮度均匀性测试的校正法研究[J].光学技术,2008,34(6):911-913
[132]丁毅,顾培夫,实现均匀照明的自由曲面反射器[J].光学学报,2007,27(3):540-544
[133]杜温锡.均匀照明和照度分布计算[J].光学机械,1978,(4):1-4
[134]田园.CCD图像对比度测试方法研究[D]:[硕士学位论文].吉林:长春理工大学
[135]朱小清等.光度测量技术及仪器,北京:中国计量出版社,1992,128-148