高分辨率LCOS光学引擎的光学系统设计
摘要
随着电视技术的发展,大屏幕、轻薄、高分辨率和像质良好将成为主流。投影电视尤其是LCOS投影电视将会是未来的发展方向之一。光学引擎是投影电视的核心部件之一。做为成像器件,要求在短距离内实现大放大倍率和无畸变清晰良好的画面质量。
本文首先介绍LCOS技术和LCOS芯片的技术特性,然后针对塑料非球面的应用介绍了塑料非球面设计的特点和设计原则;又简要介绍了光学设计原理和像差理论的知识,其中包含了远心光路的一些特点,最后分析了设计要求得到要设计的投影物镜的各个参数,结合以前设计的投影物镜,设计出符合要求的投影物镜并进行了公差分析。本文根据以往的投影物镜设计经验,分析投影物镜的结构选择,给出投影物镜的参数分配。大屏幕的投影物镜要求像质好,尤其对色差和畸变的要求很高。单个LCOS像素的大小为8.1um,通过分析投影物镜的色差要小于半个像素即4um,畸变小于0.5%。优化过程中通过玻璃材料的配合和优化函数的设定来控制色差的大小。
最终优化设计出一款折转角为90度、F数2.3、焦距为9.4mm、远心度小于1度、色差小于半个像素4um、畸变小于0.3%、投影尺寸为65英寸、总长度符合要求的LCOS投影物镜,该系统采用一片塑料非球面,所采用的玻璃材料均为国内常用玻璃材料。组后LCOS投影物镜进行了公差分析,得出了符合企业工艺性能的适合批量生产的公差数据,结果令人满意。
With the development of TV technology, large screen, thin, high resolution and image quality good will become mainstream. projection television,particularly LCOS projection television will be one of the future direction of development. Projection TV light engine is one of the core components. As imaging devices, within a short distance required to achieve a large magnification without distortion, and good clear picture quality.
This article first introduces the LCOS chip LCOS technology and technical characteristics, then for the application of plastic aspheric introduces plastic aspheric design features and design principles; and a brief description of the optical design principles and aberration theory of knowledge, which includes the distal Some optical characteristics of the final analysis of the design requirements are to design the various parameters of the projection lens, combined with previous designs of projection lens, designed to meet the requirements of the projection lens and make a tolerance analysis. Requirements of large screen projection lens demand excellent image quality, especially color and distortion. The size of a single pixel LCOS 8.1um, the color difference by analyzing the projection lens is less than half of the pixels that 4um, distortion less than 0.5%. Optimization process with the glass material by optimizing the function and color settings to control the size.
The final optimized design a turning angle of 90 degrees, F number of 2.3, the focal length is 9.4mm, less than 1 degree telemetric, lateral color is less than half a pixel 4um, distortion less than 0.3%, projection size is 65 inches, total length to meet the requirements of the LCOS projection lens, the system uses a plastic non-spherical, glass materials are used in glass materials commonly used in China. LCOS projection lens group conducted after the tolerance analysis, gets the business process performance in line with the tolerance for mass production data, with satisfactory results.
本文首先介绍LCOS技术和LCOS芯片的技术特性,然后针对塑料非球面的应用介绍了塑料非球面设计的特点和设计原则;又简要介绍了光学设计原理和像差理论的知识,其中包含了远心光路的一些特点,最后分析了设计要求得到要设计的投影物镜的各个参数,结合以前设计的投影物镜,设计出符合要求的投影物镜并进行了公差分析。本文根据以往的投影物镜设计经验,分析投影物镜的结构选择,给出投影物镜的参数分配。大屏幕的投影物镜要求像质好,尤其对色差和畸变的要求很高。单个LCOS像素的大小为8.1um,通过分析投影物镜的色差要小于半个像素即4um,畸变小于0.5%。优化过程中通过玻璃材料的配合和优化函数的设定来控制色差的大小。
最终优化设计出一款折转角为90度、F数2.3、焦距为9.4mm、远心度小于1度、色差小于半个像素4um、畸变小于0.3%、投影尺寸为65英寸、总长度符合要求的LCOS投影物镜,该系统采用一片塑料非球面,所采用的玻璃材料均为国内常用玻璃材料。组后LCOS投影物镜进行了公差分析,得出了符合企业工艺性能的适合批量生产的公差数据,结果令人满意。
With the development of TV technology, large screen, thin, high resolution and image quality good will become mainstream. projection television,particularly LCOS projection television will be one of the future direction of development. Projection TV light engine is one of the core components. As imaging devices, within a short distance required to achieve a large magnification without distortion, and good clear picture quality.
This article first introduces the LCOS chip LCOS technology and technical characteristics, then for the application of plastic aspheric introduces plastic aspheric design features and design principles; and a brief description of the optical design principles and aberration theory of knowledge, which includes the distal Some optical characteristics of the final analysis of the design requirements are to design the various parameters of the projection lens, combined with previous designs of projection lens, designed to meet the requirements of the projection lens and make a tolerance analysis. Requirements of large screen projection lens demand excellent image quality, especially color and distortion. The size of a single pixel LCOS 8.1um, the color difference by analyzing the projection lens is less than half of the pixels that 4um, distortion less than 0.5%. Optimization process with the glass material by optimizing the function and color settings to control the size.
The final optimized design a turning angle of 90 degrees, F number of 2.3, the focal length is 9.4mm, less than 1 degree telemetric, lateral color is less than half a pixel 4um, distortion less than 0.3%, projection size is 65 inches, total length to meet the requirements of the LCOS projection lens, the system uses a plastic non-spherical, glass materials are used in glass materials commonly used in China. LCOS projection lens group conducted after the tolerance analysis, gets the business process performance in line with the tolerance for mass production data, with satisfactory results.
引文
[1]迟泽英,陈文建.应用光学与光学设计基础[M].第一版,南京:东南大学出版社,2008.
[2]王之江.光学理论设计基础[M].第一版,北京:科学出版社,1985.
[3]袁旭沧.光学设计[M].第一版,北京:北京理工大学出版社,1988.
[4]王之江.实用光学技术手册,第一版,北京:机械工业出版社,2007.
[5]郁道银,谈恒英.工程光学,第二版,北京:机械工业出版社,2008.
[6]安连生应用光学[M].第三版,北京:北京理工大学出版社,2002.
[7]李晓彤,岑兆丰几何光学·像差·光学设计[M].第二版,杭州:浙江大学出版社2007.
[8]李士贤,李林.光学设计手册[M].第二版,北京:北京理工大学出版社,1996.
[9]辛企明.光学塑料非球面制造技术[M].第一版,北京:国防工业出版社,2005.
[10]赵福庭.LCOS光机中的若干问题.现代显示增刊[J].2003:119—121.
[11]夏常荣.L CO S投影技术及其市场分析[J].真空电子技术.2002(5):62—65.
[12]何平安.L Co S背投光学引擎中变焦投影物镜设计[J].应用光学.2007,28(1):59—62.
[13]梅丹阳,焦明印.变焦距投影光学系统中的远心光路设计[J].应用光学.2006,7(4):264—267.
[14]沈华.LCD光学投影系统光学引擎的光度品质分析与研究[D].南京:南京理工大学,2005.
[15]甄艳坤.Lcos微投影显示中照明系统的设计与研究[D].杭州:浙江大学,2007.
[16]王蓉.Lcos微投影仪中照明系统设计[D].杭州:浙江大学,2006.
[17]张增宝.投影显示系统光学引擎研究[D].北京:中科院研究生院,2003.
[18]陆巍.投影显示光学的理论和实验研究[D].杭州:浙江大学,2006.
[19]张向辉.背投电视的光学系统设计[J].同济大学学报,2003,31(10)
[20]龙辉.Lcos新一代投影显示技术[J].电子世界,2003(3):62—63.
[21]崔庆丰.用二元光学元件实现复消色差.光学学报[J].1994,14(8):876—881.
[22]W.T威尔.对称光学系统的像差[M].北京:科学出版社.1982.
[23]Glaser I. Applications of the lenslet array processor. SPIE.1985(564):180—185.
[24]J. B. Caldew. Compact projection optics for dual dmd projection. Society of information display.1997:917—919.
[25]F. Kahn. Projection display technologies for the new millennium. SPIE.2000(3954):84—88.
[26]Sweta Dash. Market treads in the projection display industy. SPIE.2000 (3954):2—10.
[27]杨新军.偏心和倾斜光学系统的像差特性[J].光学学报,2005,34(11)
[28]宋家军,何平安.LCOS光学引擎照明系统设计[J].光电工程,2007,32(2):32—35.
[29]匡丽娟.复眼透镜阵列应用于均匀照明系统的特性研究[J].光学与光电技术,2005,3(6):29—31.
[30]刘会刚,耿卫东.LCOS背投技术及其在中国的发展[J].现代显示,2007(2):30—34.
[31]代会娜.基于Zemax的LCOS微型投影显示镜头设计研究[D].长春:长春理工大学,2010.
[32]丁海生.基于LCOS的激光背投电视的光学设计[D].济南:山东大学,2010.
[33]庄振锋.高分辨率显微电视镜头设计[D].福州:福建师范大学,2008.
[34]杨金元.LCOS技术极其应用[J].电视技术,2004(4):59—61.
[35]贺银波,熊静懿等.LCOS投影显示技术及应用[J].光学仪器.2002,24(2):38—46.
[36]胡海旺.大屏幕投影DLP与LCD的优势分析[J].山西科技,2008(5):143—145.
[37]王金菊,宋定宇.LCD、DLP及LCOS投影机技术层面上的差异分析[J].中国西部科技,2006(1):31—32.
[38]韩景福.LCOS显示技术与LCOS背投[J].现代显示,2008(5):6—11.
[39]萧泽新.工程光学设计[M].北京:电子工业出版社,2003.
[40]张以漠.应用光学[M].天津:天津大学出版社,2003.
[41]李林,安连生.计算机辅助光学设计的理论与应用[M].第一版,北京:国防工业出版社,2002.
[42]郑荣山,李东源,阎秀生等.非球面广角镜头的设计光[J].电技术应用.2005,20(5):1—3.
[43]赵汉鼎.LCoS投影显示现状与我国LCoS产业的发展.电视技术[J].2007,31(17):49—55
[2]王之江.光学理论设计基础[M].第一版,北京:科学出版社,1985.
[3]袁旭沧.光学设计[M].第一版,北京:北京理工大学出版社,1988.
[4]王之江.实用光学技术手册,第一版,北京:机械工业出版社,2007.
[5]郁道银,谈恒英.工程光学,第二版,北京:机械工业出版社,2008.
[6]安连生应用光学[M].第三版,北京:北京理工大学出版社,2002.
[7]李晓彤,岑兆丰几何光学·像差·光学设计[M].第二版,杭州:浙江大学出版社2007.
[8]李士贤,李林.光学设计手册[M].第二版,北京:北京理工大学出版社,1996.
[9]辛企明.光学塑料非球面制造技术[M].第一版,北京:国防工业出版社,2005.
[10]赵福庭.LCOS光机中的若干问题.现代显示增刊[J].2003:119—121.
[11]夏常荣.L CO S投影技术及其市场分析[J].真空电子技术.2002(5):62—65.
[12]何平安.L Co S背投光学引擎中变焦投影物镜设计[J].应用光学.2007,28(1):59—62.
[13]梅丹阳,焦明印.变焦距投影光学系统中的远心光路设计[J].应用光学.2006,7(4):264—267.
[14]沈华.LCD光学投影系统光学引擎的光度品质分析与研究[D].南京:南京理工大学,2005.
[15]甄艳坤.Lcos微投影显示中照明系统的设计与研究[D].杭州:浙江大学,2007.
[16]王蓉.Lcos微投影仪中照明系统设计[D].杭州:浙江大学,2006.
[17]张增宝.投影显示系统光学引擎研究[D].北京:中科院研究生院,2003.
[18]陆巍.投影显示光学的理论和实验研究[D].杭州:浙江大学,2006.
[19]张向辉.背投电视的光学系统设计[J].同济大学学报,2003,31(10)
[20]龙辉.Lcos新一代投影显示技术[J].电子世界,2003(3):62—63.
[21]崔庆丰.用二元光学元件实现复消色差.光学学报[J].1994,14(8):876—881.
[22]W.T威尔.对称光学系统的像差[M].北京:科学出版社.1982.
[23]Glaser I. Applications of the lenslet array processor. SPIE.1985(564):180—185.
[24]J. B. Caldew. Compact projection optics for dual dmd projection. Society of information display.1997:917—919.
[25]F. Kahn. Projection display technologies for the new millennium. SPIE.2000(3954):84—88.
[26]Sweta Dash. Market treads in the projection display industy. SPIE.2000 (3954):2—10.
[27]杨新军.偏心和倾斜光学系统的像差特性[J].光学学报,2005,34(11)
[28]宋家军,何平安.LCOS光学引擎照明系统设计[J].光电工程,2007,32(2):32—35.
[29]匡丽娟.复眼透镜阵列应用于均匀照明系统的特性研究[J].光学与光电技术,2005,3(6):29—31.
[30]刘会刚,耿卫东.LCOS背投技术及其在中国的发展[J].现代显示,2007(2):30—34.
[31]代会娜.基于Zemax的LCOS微型投影显示镜头设计研究[D].长春:长春理工大学,2010.
[32]丁海生.基于LCOS的激光背投电视的光学设计[D].济南:山东大学,2010.
[33]庄振锋.高分辨率显微电视镜头设计[D].福州:福建师范大学,2008.
[34]杨金元.LCOS技术极其应用[J].电视技术,2004(4):59—61.
[35]贺银波,熊静懿等.LCOS投影显示技术及应用[J].光学仪器.2002,24(2):38—46.
[36]胡海旺.大屏幕投影DLP与LCD的优势分析[J].山西科技,2008(5):143—145.
[37]王金菊,宋定宇.LCD、DLP及LCOS投影机技术层面上的差异分析[J].中国西部科技,2006(1):31—32.
[38]韩景福.LCOS显示技术与LCOS背投[J].现代显示,2008(5):6—11.
[39]萧泽新.工程光学设计[M].北京:电子工业出版社,2003.
[40]张以漠.应用光学[M].天津:天津大学出版社,2003.
[41]李林,安连生.计算机辅助光学设计的理论与应用[M].第一版,北京:国防工业出版社,2002.
[42]郑荣山,李东源,阎秀生等.非球面广角镜头的设计光[J].电技术应用.2005,20(5):1—3.
[43]赵汉鼎.LCoS投影显示现状与我国LCoS产业的发展.电视技术[J].2007,31(17):49—55