基于光纤传像束的推扫式红外成像系统研究
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摘要
针对推扫式红外遥感成像技术在高分辨对地观测领域的重要地位,结合我国红外遥感技术发展现状和长线阵红外探测器技术水平,本文研究了利用线面转换的异型红外光纤传像束线阵端实现大视场推扫,面阵端每根光纤与成熟的小面阵红外焦平面阵列像元间一对一耦合获得高分辨红外遥感图像的方法。该方法规避直接获取长线阵红外探测器的技术难度,对我国红外遥感技术的发展意义重大。全文对基于红外光纤传像束的推扫式红外相机系统的工作原理、结构组成、系统像质评价方法、各光学系统的选型设计、光纤传像束与光学系统间高效率耦合等关键技术进行了论述,并进行了推扫式红外光纤传像系统原理演示实验。分析出的系统调制传递函数表达式和仿真结果可用于系统的像质评价,对其它离散采样成像系统的光学系统设计和评价也具有指导意义。所介绍的像方远心型离轴三反光学系统设计方法简单快速,利用该方法设计的Wetherell型离轴TMA光学系统不仅可作为本文红外相机的前置望远系统,还可用作成像光谱仪等其它要求像方远心结构的各类仪器中。所设计的两种型式后继耦接系统结构参数、成像质量、温度灵敏度和公差分析结果等均满足设计要求,还可用作其它要求100%冷光阑效率的红外中继系统。所设计的用于红外光纤传像束耦合的微透镜阵列解决了系统填充率低、焦比退化引起耦合损耗大等问题,模拟结果表明,引入微透镜后可使系统的光能利用率提高40%以上,且所述设计方法还可设计用于红外焦平面耦合的微透镜阵列。最后进行了光纤传像红外系统推扫成像演示实验,获得了良好像质的拼接图像,实验结果及分析表明利用红外光纤传像束实现推扫成像具有可行性和优越性,为后续进一步的原理样机实现奠定了基础。
For the push-broom infrared remote sensing imaging technology plays animportant role in the high-resolution earth observation, but the internal developmentof infrared imaging technology has been baffled by the technical level of long-lineararray infrared detector, the use of line-plane-switching infrared fiber bundle toachieve high-resolution push-broom infrared imaging has been studied in thisdissertation. In this method the linear array end of the imaging fiber bundle is usedas a long-linear array infrared detector and the plane array end of the bundle iscoupled by a mature small infrared focal plane array with the single fibercorresponding to the pixel of the focal plane one by one. It can evade the difficultyto get the long-linear array infrared detector directly, and has a signally significanceto the development of our country's infrared imaging technology. This dissertationintroduces the composition, working principle and optical system design process ofthis novel infrared optical system particularly. And the key technology, such ashigh-efficiency coupling method, system pupil matching, and image qualityevaluation method of the system has been discussed respectively. Meanwhile, theexperiments to prove the feasibility of the system have been completed. Theexpression of the system’s modulation transfer function can be used for the imagequality evaluation of other similar discrete sampling imaging system. The opticalsystem design result and method of the telecentric structure off-axis TMA foretelescope system can also be used for the design of imaging spectrometer foretelescope. The designed two structure successor coupling system have good imagequality, small size, low temperature sensitivity and loose tolerance, which couldmeet the requirements of the100%cold diaphragm matching infrared relay system.The use of the microlens arrays for infrared fiber bundle coupling could solve theproblems, such as low fill factor, coupling loss caused by the focal ratio degradation of fibers and other issues, availably. The simulation results showed that the couplingefficiency of the system could be improved by40%. The design method of themicrolens arrays is also suitable for the microlens arrays coupling with infrared focalplane arrays. Finally, the system principle-demonstrating experiment has beenaccomplished, the results of which prove that the push-broom infrared camera basedon the imaging fiber bundle is feasibility and superiority. This experiment is thefoundation for the subsequent further verification experiments.
For the push-broom infrared remote sensing imaging technology plays animportant role in the high-resolution earth observation, but the internal developmentof infrared imaging technology has been baffled by the technical level of long-lineararray infrared detector, the use of line-plane-switching infrared fiber bundle toachieve high-resolution push-broom infrared imaging has been studied in thisdissertation. In this method the linear array end of the imaging fiber bundle is usedas a long-linear array infrared detector and the plane array end of the bundle iscoupled by a mature small infrared focal plane array with the single fibercorresponding to the pixel of the focal plane one by one. It can evade the difficultyto get the long-linear array infrared detector directly, and has a signally significanceto the development of our country's infrared imaging technology. This dissertationintroduces the composition, working principle and optical system design process ofthis novel infrared optical system particularly. And the key technology, such ashigh-efficiency coupling method, system pupil matching, and image qualityevaluation method of the system has been discussed respectively. Meanwhile, theexperiments to prove the feasibility of the system have been completed. Theexpression of the system’s modulation transfer function can be used for the imagequality evaluation of other similar discrete sampling imaging system. The opticalsystem design result and method of the telecentric structure off-axis TMA foretelescope system can also be used for the design of imaging spectrometer foretelescope. The designed two structure successor coupling system have good imagequality, small size, low temperature sensitivity and loose tolerance, which couldmeet the requirements of the100%cold diaphragm matching infrared relay system.The use of the microlens arrays for infrared fiber bundle coupling could solve theproblems, such as low fill factor, coupling loss caused by the focal ratio degradation of fibers and other issues, availably. The simulation results showed that the couplingefficiency of the system could be improved by40%. The design method of themicrolens arrays is also suitable for the microlens arrays coupling with infrared focalplane arrays. Finally, the system principle-demonstrating experiment has beenaccomplished, the results of which prove that the push-broom infrared camera basedon the imaging fiber bundle is feasibility and superiority. This experiment is thefoundation for the subsequent further verification experiments.
引文
岳涛,黄宇民,刘品雄,侯宇葵,周一鸣.未来中国卫星遥感器的发展分析[J].航天器工程,2008,17(4):77-82.
[2]刘兆军,周峰,李瑜.航天光学遥感器对红外探测器的需求分析[J].红外与激光工程,2008,(37)1:25-29.
[3]我国高分辨率对地观测系统将于2020年全面形成[J].红外,2012,4.
[4]魏建中.应用于红外跟踪系统的光纤耦合技术[J].光学技术,1994,3:12-15.
[5]安博文.超高分辨率异型传像光纤束中的空间变换[J].光电工程,2006,33(11):83-87.
[6]安博文,陈桂林.光纤耦合系统中非均匀性校正[J].红外技术,2007,29(5):261-264.
[7] Bowen An, Bingbin Xue, Shengda Pan. Sub-pixel processing for super-resolution scanningimaging system with fiber bundle coupling[J]. CHINESE OPTICS LETTERS,2011,9(8):081001-1-4.
[8]夏亚茜.国外遥感卫星现状简介[J].国际太空,2012,9:21-30.
[9]王金堂,乌崇德.国外几种星载光学遥感器的发展情况简介[J].航天返回与遥感,2002,23(2):15-20.
[10]丁延卫,王立国.美国的EO-1高级对地观测遥感器[J].光机电信息,2002,2:30-34.
[11] Lencioni D E, Digenis C J, Bicknell W E, Hearn, et al. Design and Performance of the EO-1Advanced Land Imager[J]. SPIE,1999,3870:269-280.
[12]冯钟葵,石丹,陈文熙.法国遥感卫星的发展-从SPOT到Pleiades[J].遥感数据,2007,4:87-92.
[13] D.Seguela, C.Fratter, P.Munier. SPOT-5System[A]. SPIE,1999,3750:212-220.
[14]龚燃.斯波特-6卫星于9月升空[J].国际太空,2012,9:9-13.
[15] Moriyama T, MTSAT-1R. A Multifunctional Satellite for Japan and the Asia-Pacific Region.Proceedings of the56th IAC, IAC-05-B3.2.04[C]. Fukuoda, Japan,2005.
[16] Yuji Osawa, Kenichi Toda, Hiroyuki Wakabayashi, et al. Advanced Land Observing Satellite(ALOS) Mission Objectives and Payloads. Proc. of the MOMS symposium[C]. Koeln, Germany,1995.
[17] http://www.isro.gov.in/newsletters/contents/spaceindia/apr2011-dec2011/article3.htm
[18]Brochure of ResourceSat-2, NRSC, URL:http://www.nrsc.gov.in/assets/doc/brochures/resourcesat2.pdf
[19]行麦玲,刘兆军.资源卫星光学遥感器发展近况[J].航天返回与遥感,2004,(25)3:17-24.
[20]范晋祥,岳艳军.军用红外成像系统新概念新体制的发展[J].红外与激光工程,2011,40(1):1-6.
[21] S.Meshcat, J.L.Stufflebeam. Optical tracking algorithm-a DSP approach[A]. SPIE[C].1995,2468:68-79.
[22]王群.美国新一代导弹预警卫星系统及其能力分析[J].国防科技,2012,2:7-13.
[23]林海,王世光,曹代强.美弹道导弹防御系统中光电系统的发展现状[J].飞航导弹,2010,1:24-27.
[24]袁俊.弹道导弹预警关键技术的应用发展.中国航天,2002,11:10-13.
[25]天兵.美国发射首颗“天基红外系统”地球静止轨道卫星[J].国际太空,2011,05:40-48.
[26]蒋跃,邓磊,臧鹏.美国天基红外预警系统的发展现状和技术特点[J].空军雷达学院学报,2011,25(2):105-109.
[27]夏德深,谢君.从CBERS-1卫星红外数据看中国遥感器研制[J].航天返回与遥感,2001,22(1):55-62.
[28]中国的资源探测卫星(上)[J].中国航天,2008,(12):15-17.
[29]资源三号卫星. http://baike.baidu.com/view/2728902.htm
[30]刘银年,王建宇,薛永祺.环境减灾-1B卫星红外相机的研制[J].航天器工程,2009,18(6):50-56.
[31]中国的资源探测卫星(下)[J].中国航天,2009,(1):11-12.
[32]龚海梅,刘大福.航天红外探测器的发展现状与进展[J].红外与激光工程,2008,37(1):18-24.
[33] Pierre CASTELEIN, Philippe RAMBAUD, Jean-Paul CHAMONAL, et al. New generationof long linear butted HgCdTe arrays for high resolution infrared imaging[J]. Proc. of SPIE,2002,4721:252-260.
[34] J. P. Chamonal, E. Mottin, P. Audebert, P. Médina, M. Ravetto, et al.1500-element linearMWIR and LWIR HgCdTe arrays for high resolution imaging[J]. Proc. of SPIE,1997,3821:384-394.
[35] Philippe Feautrierai, Jean-Luc Gachbi, Mark Downing, et al. Advances in DetectorTechnologies for Visible and Infrared Wavefront Sensing[J]. Proc. of SPIE,8447:84470Q-1-33.
[36]龚海梅,邵秀梅,李向阳,等.航天先进红外探测器组件技术及应用[J].红外与激光工程,2012,41(12):3129-3141.
[37]刘武,叶振华.国外红外光电探测器发展动态[J].激光与红外,2011,41(4):365-370.
[38] M. Mai, I. Rühlich, Th. Wiedmann, C. Rosenhagen. Development trends in IR detectorcoolers[J]. Proc. of SPIE,2009,7298:729819-1-7.
[39]赵江.红外探测技术的现状与发展趋势[J].舰船电子工程,2007,27(1):32-38.
[40]史衍丽.第三代红外探测器的发展与选择[J].红外技术,2013,35(1):1-7.
[41]龚海梅,张可锋,唐恒敬,等. InGaAs近红外线列焦面阵的研制进展[J].红外与激光工程,2009,38(1):14-19.
[42]范宏波.基于1152×6长波线列探测器的高性能红外搜索预警系统[J].红外技术,2010,32(1):20-24.
[43]王小坤,曾智江,朱三根,等.中波2048元长线列碲镉汞焦平面杜瓦组件[J].红外与激光工程,2011,40(4):611-615.
[44] Joel Bernier, Patrick Plainchamp, Dominique Bardon. Infrared pushbroom camera breadbordusing off the shelf2D array of detector[J]. SPIE,1994,2209:262-274.
[45] Arnold Daniels, Till W. Liepmann. A fiber-optically coupled infrared focal plane array systemfor use in missile warning receiver applications[J]. SPIE,1999,3701:118-130.
[46] Gang Wang, Jianlin Lia, Xinbo Zheng, et al. Infrared scanning imaging system based on IRfiber bundle[J]. Proc. of SPIE,2010,7854:25-30.
[47]安博文,潘胜达,陈桂林.基于卡尔曼滤波器的传像光纤束位置搜索[J].红外与毫米波学报,2010,29(2):156-160.
[48]李坤宇.无源光纤传像系统传像质量的评价与优化研究[D].南京:南京理工大学博士学位论文,2001,6:1-50.
[49] Israel Gannota, Alon Gorena, Eran Rave, et al. Thermal Imaging through InfraredFiber/Waveguides Bundles[J]. Proc. of SPIE,2004,5317:94-100.
[50]李响,梁中翥,郭鹏,等.光纤传像束研究进展[J].光机电信息,2009,26(7):24-31.
[51] Eran Rave, Abraham Katzir. Ordered bundles of infrared transmitting silver halide fbers:attenuation, resolution and crosstalk in long and fexible bundles[J]. Opt. Eng.,2002,41(7):1467-1468.
[52] M. Yangwn, H. Lin. The crosstalk study of order-packed flexible image bundles[J]. Proc. ofSPIE,1998,3552:232-237.
[53] A. RAY HILTON SR. Infrared imaging bundle development at Amorphous Materials. SPIE,1999,3849:60-66.
[54] M. Saito, M. Takizawa, S. Sakuragi, F. Tanei. Infrared image guide with bundled As-S glassfibers[J]. Appl. Opt.1985,24(15):2304-2319.
[55] A. R. Hilton Sr., A. R. Hilton Jr., J. McCord. Infrared imaging with fiber optic bundles[J].Proc. of SPIE,2003, Vol.5074:849-854.
[56]吕步云,杨克武,薛洪达,等.2m长As-Se-Te玻璃红外光纤传像束[J].红外与激光工程,2001,30(5):357-360.
[57]陈月存.新型工业内窥镜的研究[D].长春:长春理工大学硕士论文,2009,3:20-28.
[58] Dongyuan Li, Lantian Hou, Guiyao Zhou. Design of imaging fber bundle lens with binaryoptical surface[J]. Optical Engineering,2007,46(2):023202-1-5.
[59]李东源,阎秀生,张晓光,等.传像光纤束的折-衍混合耦接器[J].中国激光,2006,33(9):1210-1213.
[60]周胜利.三线阵TDI CCD在测图卫星中的应用分析[J].航天器工程,2007,16(4):19-22.
[61] Liu Xinping, WEN Desheng, QIAO Wei, et al. Subpixel imaging technique[J]. SPIE,1999,3832:158-162.
[62]周峰,王世涛,王怀义.关于亚像元成像技术几个问题的探讨[J].航天返回与遥感,2002,23(4):26-33.
[63]安博文,薛冰玢.光纤耦合的亚像元图像超分辨率重建[J].计算机工程,2012,38(17):222-226.
[64] E. Carrasco, I. R. Parry. A method for determining the focal ratio degradation of optical fibresfor astronomy[J]. Mon. Not. R. Astron., Soc.271.
[65]程欣.大视场光纤成像光谱仪光学系统研究[D].北京:中国科学院研究生院,2012,5:78-90.
[66]张勇,赵达尊.离散成像系统的光学传递函数[J].北京理工大学学报,1997,17(4):151-l55.
[67]王春红,向阳.基于超光谱成像探测系统的线阵CCD的调制传递函数特性研究[J].光谱学与光谱分析,2009,29(6):1478-1481.
[68]李宏升.超光谱成像仪成像链的调制传递函数研究[D].中国科学院长春光学精密机械与物理研究所博士学位论文.2005,12.
[69] Xu He, Yang Xiang. Study on a method of evaluating the alignment of pixels betweenfiber-optic image bundles and detector arrays[J]. Appl. Opt.2011,50(25):189-193.
[70] W Wittenstein, J. C. Fontanella, A. R. Newbery, J. Baars. The definition of the OTF and themeasurement of abasing for sampled imaging system [J]. Opt. Acta,1982,29:41-50.
[71]S. K. Park, R. A. Schowengerdt, M. A. Kaczynski. Modulation-transfer-function analysis forsampled image system[J]. Appl. Opt.1984,23:2572-2582.
[72] RENEE DROUGARD. Optical Transfer Properties of Fiber Bundles[J]. Journal of the opticalsociety of America.1964,54(7):907-915.
[73] L. D. Luca, G Cardone. Modulation transfer function cascade model for a sampled IRimaging system [J]. Appl. Opt.1991,30(13):1659-1664.
[74]金光,钟兴. CCD光学遥感器参数选择研究[J].空间科学学报,2009,29(1):135-139.
[75] M.A. Player. Spread Functions and Modulation Transfer Functions of Fibre-optic Bundles[J].Journal of Modern Optics,1988,35(8):1363-1372.
[76] A. Arefiev, Method for evaluation of fibre optic components MTF[J]. Proc. of SPIE,1995,2507:211-217.
[77] N. S. KAPANY, J. A. EYER, R. E. KEim. Fiber Optics. Part II. Image Transfer on Static andDynamic Scanning with Fiber Bundles[J]. Journal of the optical society of America,1957,47(5):423-427.
[78] K. M. Hock, Effect of oversampling in pixel arrays[J]. Opt. Eng.1995,34:1281-1288.
[79] Hui W, Yang X, and Bingxi Y. Average modulation transfer function of line-array fiber-opticimage bundles[J]. Chin. Opt. Lett.,2(8):453-455.
[80] M. E. Marhic, S. E. Schacham, M. Epstein. Misalignment in imaging multifibers[J]. Appl.Opt.1978,17(21):3503-3506.
[81] J. C. Feltz, M. A. Karim. Modulation transfer function of charge-coupled devices[J]. Appl.Opt.1990,29(5):717-722.
[82]程欣,王晶,张葆,洪永丰.光纤成像光谱仪中谱线畸变对调制传递函数的影响[J].光谱学与光谱分析.2011,31(10):2861-2864.
[83]史光辉.卫星对地观测高分辨率光学系统和设计问题[J].光学精密工程,1999,10(2):16-24.
[84]陈浩锋,李英才,樊超,等.宽视场长焦距离轴三反射镜光学系统的设计[J].光子学报,2007,36(S1):142-145.
[85]王立辉,郁蕴健,陆段军.大线视场大相对口径红外成像系统的光学设计[J].红外与毫米波学报,2008,27(1):39-41.
[86] FISCHER R E, TADIC-GALEB B. Optical System Design[M]. McGraw-Hill,2000:43-47,250-254.
[87]张登臣,郁道银.实用光学设计方法与现代光学系统[M].北京:机械工业出版社,1995.
[88]韩昌元.高分辨力空间相机的光学系统[J].光学精密工程,2008,16(11):2164-2172.
[89]李晓彤,岑兆丰.几何光学·像差·光学设计[M].浙江:浙江大学出版社,2003:208-216.
[90]张鑫,贾宏光,张跃.远距型红外消热差物镜设计[J].红外与激光工程,2012,41(1):78-183.
[91]张以谟.应用光学(第三版)[M].北京:电子工业出版社,2008.
[92]李幼平,禹秉熙,韩昌元,等.成像光谱仪工程权衡优化设计的光学结构[J].光学精密工程,2006,14(6):974-979.
[93]丛杉珊.大视场长焦距反射式空间光学系统设计[D].长春:长春理工大学,2008:3-8.
[94]宫广彪.超光谱成像仪前置成像物镜设计[D].苏州:苏州大学硕士学位论文,2009,4:8-9.
[95]史黎丽.航天遥感相机光学系统设计研究[D].哈尔滨:哈尔滨工业大学工学硕士学位论文.2007,7:13-17.
[96] https://directory.eoportal.org/web/eoportal/satellite-missions/c-missions/cartosat-2b
[97] Marc Postman, Tom Brown, Kenneth, et al. Sembach Advanced Technology Large-ApertureSpace Telescope: science drivers and technology developments[J]. Optical Engineering,2012,51(1):011007-1-11.
[98] Jun-ichi Ishigakia, Toshihiro Okamuraa, Kunihiro Tanikawaa. Designing and Testing ofOff-axis Three-Mirror Optical System for Multi-Spectral Sensor[J]. SPIE,3061:356-369.
[99]宋岩峰,邵晓鹏,徐军.离轴三反射镜光学系统研究[J].红外与激光工程,2008,37(4):706-709.
[100]潘君骅.光学非球面的设计、加工与检验[M].苏州:苏州大学出版社,2004:21-37,130-141.
[101]杨建峰,安葆青,薛鸣球.大视场三反射面非共轴光学系统研究[J].光子学报,1997,26(3):277-281.
[102]常军,翁志成,姜会林,等.长焦距空间三反光学系统的设计[J].光学精密工程,2001,9(4):315-318.
[103] BRCT-DIBAT T, ALBOUYS V, BERTHON J, et al.. Yest of a high resolution three mirroranastigmat telescope [J]. SPIE,2000,3870:128-137.
[104]金光,张亮,胡福生.大F数高分辨率空间望远镜光学系统[J].光学精密工程,2007,15(2):155-159.
[105]李旭阳,李英才,马臻,易红伟.高分辨率空间相机共轴三反光学系统实现形式研究[J].应用光学,2009,30(5):717-723.
[106] Michael. Lidwell. Mirror telescope for long linear detector arrays[J]. SPIE,1998,3429:19-30.
[107]杨秉新.美国IKONOS和QuickBird2卫星相机的主要性能和特点分析及看法[J].航天返回与遥感,2002,23(4):10-12.
[108] Pleiades Programme Overview[M]. Presentation of SPOT IMAGE Direct Receiving StationMeeting,2006.
[109] LAMPTON M L, SHOLL M J. Comparison of on-axis three-mirror-anastigmat telescopes[J].SPIE,2007,6687:66870S-1-8.
[110]张科科,阮宁娟,傅丹鹰.国外空间用三反离轴相机发展分析与思考[J].航天返回与遥感,2008,29(3):63-70.
[111] Roland GEYL. Design and fabrication of a Three Mirror Flat Field Anastigmat for highresolution earth observation[J]. SPIE,2210:739-746.
[112] FIGOSKI J W. Development of three-mirror wide-field sensor from paper design tohardware[J].SPIE,1989,1113:126-133.
[113]陈浩峰.用于空间相机的离轴反射式光学系统研究[D].北京:中国科学院研究生院硕士学位论文,2007,7:14-16.
[114]刘晓梅,向阳.宽视场成像光谱仪前置远心离轴三反光学系统设计[J].光学学报,2011,31(6):0622004-1-4.
[115] Joey Espejo, Ginger Drake, Karl Heuerman, et al.. A hyperspectral imager for highradiometric accuracy Earth climate studies[J]. Proc. of SPIE,8158:81580B-1-9.
[116]刘晓梅,向阳.具有实入瞳的远心离轴三反系统研究与设计[J].光学学报,2011,31(11):1122002-1-4.
[117]王美钦,王忠厚,白加光.成像光谱仪的离轴反射式光学系统设计[J].红外与激光工程,2012,41(1):167-172.
[118] W. B. Wetherell. Image quality criteria for the large space telescope[C]. NationalAcademy of Sciences, Washington, D.C.,1974.55-103.
[119]李欢,向阳.10°远心离轴三反消象散望远系统的光学设计[J].光子学报,2009,38(9):2256-2259.
[120]薛庆生,黄煜,林冠宇.大视场高分辨力星载成像光谱仪光学系统设计[J].光学学报,2011,31(8):0822001-1-6.
[121]刘新平,杨建峰.折轴三反射镜成象光学系统结构研究[J].光子学报,1998,27(1):73-76.
[122] Joseph M. Geary. Introduction to lens design with practical ZEMAX example. USA Virginia:Willmann-Bell,Inc.2002.
[123] R. Barry Johnson. Wide field of view three-mirror telescope having a common opticalaxis[J]. Opt.Eng,1988,27(12):1046-1050.
[124]郭永祥,李英才,梁天梅,等.一种大视场离轴三反射光学系统研究[J].光学学报,2010,30(9):2680-2683.
[125] Kunihiro Tanikawa, Toshihiro Okamura, Jun-ichi Kudo, Hideo Wada, Hiromichi Shirahata.Six band multispectral sensor using off-axis three-mirror reflective optics[J]. Opt. Eng.2000,39(10):2781-2788.
[126] Anna-Britt Mahler, Russell Chipman. Tolerancing and alignment of a three-mirror off-axistelescope[J]. Proc. of SPIE,6676:66760I-1-8.
[127]杨晓飞,韩昌元.利用离轴三反镜光学系统确定各镜的装调公差[J].光学技术,2005,31(2):173-176.
[128]张登臣,郁道银.实用光学设计方法与现代光学系统[M].北京:机械工业出版社,1995.
[129]杨晓飞,张晓辉,韩昌元. ZEMAX软件在离轴三反射镜系统计算机辅助装调中的应用[J].光学精密工程,2004,12(3):270-274.
[130] Allen mann.Infrared optics and zoom lenses[M]. SPIE.2009.
[131]赵秀丽.红外光学系统设计[M].北京:机械工业出版社,1986.
[132]杨福兴.非球面光学零件的超精密磨削技术[J].机械工艺师,1998,6:13-14.
[133]温午麒,康建翊,丁欣,等.用非球面透镜制作光纤的1:1空间耦合器[J].光子学报,2012,41(3):294-298.
[134]宋岩峰.现代红外光学系统设计[D].西安:西安电子科技大学硕士学位论文,2008,1:11-20.
[135]刘玉娟,唐玉国,崔继承,巴音贺希格,齐向东.红外成像光谱测量中Dyson光学系统的研究进展[J].光谱学与光谱分析,2012,32(2):548-552.
[136]付强,黄旻,景娟娟,相里斌.用于液晶可调谐滤光片型多光谱成像仪的中继成像系统设计[J].光学学报,2011,31(10):10220021-10220025.
[137]沈为民,薛鸣球,余建军.大视场大相对孔径长波红外物镜[J].光子学报,2004,4:460-463.
[138]沈为民,薛鸣球,余建军.长波红外广角地平仪镜头的光学设计[J].光学精密工程,2002,8:329-332.
[139]杨胜杰.高分辨率制冷型中波广角红外成像系统的光学设计[J].光学学报,2002,8:08220031-08220036.
[140]向鹏飞,李贝,袁安波.一种新的微透镜阵列制作技术[J].半导体光电,2012,33(2):197-200.
[141] Masaharu Deguchi, Takesuke Maruyama, Futoshi Yamasaki. Microlens design usingsimulation for CCD image sensor[J]. IEEE Transactions on Consumer Electronics,1992,38(3):583-589.
[142]吴振华,易新建,麦志洪等. IRCCD微透镜阵列的计算机模拟设计与分析[J].光电子2激光,1998,9(2):110-112.
[143]孙艳军,冷雁冰,陈哲,董连和.用于红外焦平面的正方形孔径球面微透镜阵列研究[J].光子学报,2012,41(4):399-403.
[144]孙艳军,冷雁冰,陈哲,董连和.硅基自由曲面光学微透镜阵列制作的光学性能研究[J].红外技术,2012,34(1):44-47.
[145] Deqing Ren, Jeremy Allington-Smith, Ray Sharples, George Dodsworth. The design andconstruction of a Multiple-Integral-Field-Unit for8-meter Telescopes[J]. Proceedings of SPIE Vol.4842,2003,384-391.
[146] Ren Yang, Steven A. Soper, Wanjun Wang. Microfabrication of pre-aligned fber bundlecouplers using ultraviolet lithography of SU-8[J]. Sensors and Actuators A,2006,(127):123-130.
[147] Ian R. Parry. Optical fbres for integral feld spectroscopy[J]. New Astronomy Reviews,2006,50:301-304.
[148] Daniel V. Hahn, David M. Brown, Nathan W. Rolander, et al.. Fiber optic bundle array widefield-of-view optical receiver for free space optical communications[J]. OPTICS LETTERS,2010,35,(21):3559-3561.
[149] Andrea M. Brown, Daniel V. Hahn, David M. Brown, et al.. Experimental implementation offiber optic bundle array wide FOV free space optical communications receiver[J]. APPLIEDOPTICS,2012,51(18):3995-4002.
[150]阎嫦玲,鲁平,刘德明,等.与光纤阵列耦合的微透镜阵列设计与损耗分析[J].光电子·激光,2006,17(9):1044-1047.
[151]李佳.用于传像光纤束集成的折射微透镜阵列研究[D].武汉:华中科技大学,2008:24-46.
[152] Haynes Dionne M, Withford Michael J, Dawes Judith M, et al. Focal ratio degradation: Anew perspective[J]. Proc. of SPIE,2008,7018.
[153]王森,朱冰.大芯径光谱传光光纤焦比退化特性研究.光电工程,2011,38(7):17-24.
[154]董艳,朱冰. LAMOST传光光纤的焦比退化特性分析[J].中国科学技术大学学报,2007,37(6):606-611.
[155] Murphy J D, MacQueen P J. Focal Ratio Degradation and Transmission in VIRUS-P OpticalFibers[J]. Pro. of SPIE,2008,7018:70182T.1-70182T.12.
[156] Gerardo Avila, Paul Singh, Maja Albertsen. Photometrical scrambling gain and focal ratiodegradation in fibers for astronomical instruments[J]. Pro. of SPIE,2006,6269:626950-1-9.
[157] S. Arribas, E. Mediavilla. Integral field spectroscopy with optical fibers: studies of thecircumnuclear regions of nearby active galactic nuclei[J]. ASP conference series,2000,195:295-306.
[158] Ramsey Lawrence W. Focal ratio degradation in optical fibers of astronomical interest[J].Astronomical Society of the Pacific,1988,3:26-39.
[159]柯才军.微透镜阵列的设计、制作及与CCD的集成技术[D].武汉:华中科技大学博士学位论文,2005,4:8-12.
[160]张玉.六角形孔径平面微透镜阵列研究[D].重庆:西南大学硕士学位论文,2007,4:10-11.
[161]刘德森.微透镜阵列与微小光学[J].光子学报.1994,23(z2):67-76.
[162]马相路.光纤传像束原理及其应用[J].光机电信息,2007,24(10):44-49.
[163]任智斌,朱丽思,曾皓,姜会林.微透镜阵列的光刻胶热熔制作技术[J].长春理工大学学报,2006,12:15-20.
[164] Z D Popovic, R A Spague, G A Neville Connell. Techniques for Monolithic Fabrication ofMicrolens Arrays. Applied Optics,1988,27:1281-1284.
[165]张新宇,易新建,何苗,赵兴荣.面阵IRCCD摄像芯片用折射微透镜阵列的离子束刻蚀制作[J].电子学报,1999,27(8):135-136.
[166] ZHANG Feng-jun, ZHOU Su-mei, JIANG Xiao-ping, Liu De-sen. Fabrication of PlanarSquare Aperture Microlens Array. ACTA PHOTONICA SINICA,2008,37(S2):202-203.
[167] ZHANG Xinyu, YI Xinjian, HE Miao, ZHAO Xingrong. Large-area Quartz Glass MicrolensArray Fabricated by lon Beam Etching for Focal Plane Detectors[J]. J. Infrared Millim.Waves,1999,18(2):97-105.
[168]麦志洪,易新建,赵兴荣,郝建华.用于红外焦平面的微透镜阵列单片制备技术[J].华中理工大学学报,1996,24(7):77-79.
[169]任智斌,卢振武.通过缩短显影时间提高微透镜阵列的填充因子与F数[J].光电子·激光,2005,16(2):150-154.
[170]刘德森,高应俊.微小光学与微小光子器件[J].光子学报,1997,26(Z1):21-27.
[171]于双双.微透镜阵列光学耦合扩束技术研究[D].哈尔滨:哈尔滨工业大学,2011,6.
[172]刘德森,蒋小平.微小光学与异形孔径微透镜阵列研究[J].激光与光电子学进展,2010,47,083501-1-16.
[173] XIANG Peng-fei, LI Bei, YUAN An-bo. New fabrication technology of Microlens array[J].Semiconductor Optoelecronics,2012,33(2):197-200.
[2]刘兆军,周峰,李瑜.航天光学遥感器对红外探测器的需求分析[J].红外与激光工程,2008,(37)1:25-29.
[3]我国高分辨率对地观测系统将于2020年全面形成[J].红外,2012,4.
[4]魏建中.应用于红外跟踪系统的光纤耦合技术[J].光学技术,1994,3:12-15.
[5]安博文.超高分辨率异型传像光纤束中的空间变换[J].光电工程,2006,33(11):83-87.
[6]安博文,陈桂林.光纤耦合系统中非均匀性校正[J].红外技术,2007,29(5):261-264.
[7] Bowen An, Bingbin Xue, Shengda Pan. Sub-pixel processing for super-resolution scanningimaging system with fiber bundle coupling[J]. CHINESE OPTICS LETTERS,2011,9(8):081001-1-4.
[8]夏亚茜.国外遥感卫星现状简介[J].国际太空,2012,9:21-30.
[9]王金堂,乌崇德.国外几种星载光学遥感器的发展情况简介[J].航天返回与遥感,2002,23(2):15-20.
[10]丁延卫,王立国.美国的EO-1高级对地观测遥感器[J].光机电信息,2002,2:30-34.
[11] Lencioni D E, Digenis C J, Bicknell W E, Hearn, et al. Design and Performance of the EO-1Advanced Land Imager[J]. SPIE,1999,3870:269-280.
[12]冯钟葵,石丹,陈文熙.法国遥感卫星的发展-从SPOT到Pleiades[J].遥感数据,2007,4:87-92.
[13] D.Seguela, C.Fratter, P.Munier. SPOT-5System[A]. SPIE,1999,3750:212-220.
[14]龚燃.斯波特-6卫星于9月升空[J].国际太空,2012,9:9-13.
[15] Moriyama T, MTSAT-1R. A Multifunctional Satellite for Japan and the Asia-Pacific Region.Proceedings of the56th IAC, IAC-05-B3.2.04[C]. Fukuoda, Japan,2005.
[16] Yuji Osawa, Kenichi Toda, Hiroyuki Wakabayashi, et al. Advanced Land Observing Satellite(ALOS) Mission Objectives and Payloads. Proc. of the MOMS symposium[C]. Koeln, Germany,1995.
[17] http://www.isro.gov.in/newsletters/contents/spaceindia/apr2011-dec2011/article3.htm
[18]Brochure of ResourceSat-2, NRSC, URL:http://www.nrsc.gov.in/assets/doc/brochures/resourcesat2.pdf
[19]行麦玲,刘兆军.资源卫星光学遥感器发展近况[J].航天返回与遥感,2004,(25)3:17-24.
[20]范晋祥,岳艳军.军用红外成像系统新概念新体制的发展[J].红外与激光工程,2011,40(1):1-6.
[21] S.Meshcat, J.L.Stufflebeam. Optical tracking algorithm-a DSP approach[A]. SPIE[C].1995,2468:68-79.
[22]王群.美国新一代导弹预警卫星系统及其能力分析[J].国防科技,2012,2:7-13.
[23]林海,王世光,曹代强.美弹道导弹防御系统中光电系统的发展现状[J].飞航导弹,2010,1:24-27.
[24]袁俊.弹道导弹预警关键技术的应用发展.中国航天,2002,11:10-13.
[25]天兵.美国发射首颗“天基红外系统”地球静止轨道卫星[J].国际太空,2011,05:40-48.
[26]蒋跃,邓磊,臧鹏.美国天基红外预警系统的发展现状和技术特点[J].空军雷达学院学报,2011,25(2):105-109.
[27]夏德深,谢君.从CBERS-1卫星红外数据看中国遥感器研制[J].航天返回与遥感,2001,22(1):55-62.
[28]中国的资源探测卫星(上)[J].中国航天,2008,(12):15-17.
[29]资源三号卫星. http://baike.baidu.com/view/2728902.htm
[30]刘银年,王建宇,薛永祺.环境减灾-1B卫星红外相机的研制[J].航天器工程,2009,18(6):50-56.
[31]中国的资源探测卫星(下)[J].中国航天,2009,(1):11-12.
[32]龚海梅,刘大福.航天红外探测器的发展现状与进展[J].红外与激光工程,2008,37(1):18-24.
[33] Pierre CASTELEIN, Philippe RAMBAUD, Jean-Paul CHAMONAL, et al. New generationof long linear butted HgCdTe arrays for high resolution infrared imaging[J]. Proc. of SPIE,2002,4721:252-260.
[34] J. P. Chamonal, E. Mottin, P. Audebert, P. Médina, M. Ravetto, et al.1500-element linearMWIR and LWIR HgCdTe arrays for high resolution imaging[J]. Proc. of SPIE,1997,3821:384-394.
[35] Philippe Feautrierai, Jean-Luc Gachbi, Mark Downing, et al. Advances in DetectorTechnologies for Visible and Infrared Wavefront Sensing[J]. Proc. of SPIE,8447:84470Q-1-33.
[36]龚海梅,邵秀梅,李向阳,等.航天先进红外探测器组件技术及应用[J].红外与激光工程,2012,41(12):3129-3141.
[37]刘武,叶振华.国外红外光电探测器发展动态[J].激光与红外,2011,41(4):365-370.
[38] M. Mai, I. Rühlich, Th. Wiedmann, C. Rosenhagen. Development trends in IR detectorcoolers[J]. Proc. of SPIE,2009,7298:729819-1-7.
[39]赵江.红外探测技术的现状与发展趋势[J].舰船电子工程,2007,27(1):32-38.
[40]史衍丽.第三代红外探测器的发展与选择[J].红外技术,2013,35(1):1-7.
[41]龚海梅,张可锋,唐恒敬,等. InGaAs近红外线列焦面阵的研制进展[J].红外与激光工程,2009,38(1):14-19.
[42]范宏波.基于1152×6长波线列探测器的高性能红外搜索预警系统[J].红外技术,2010,32(1):20-24.
[43]王小坤,曾智江,朱三根,等.中波2048元长线列碲镉汞焦平面杜瓦组件[J].红外与激光工程,2011,40(4):611-615.
[44] Joel Bernier, Patrick Plainchamp, Dominique Bardon. Infrared pushbroom camera breadbordusing off the shelf2D array of detector[J]. SPIE,1994,2209:262-274.
[45] Arnold Daniels, Till W. Liepmann. A fiber-optically coupled infrared focal plane array systemfor use in missile warning receiver applications[J]. SPIE,1999,3701:118-130.
[46] Gang Wang, Jianlin Lia, Xinbo Zheng, et al. Infrared scanning imaging system based on IRfiber bundle[J]. Proc. of SPIE,2010,7854:25-30.
[47]安博文,潘胜达,陈桂林.基于卡尔曼滤波器的传像光纤束位置搜索[J].红外与毫米波学报,2010,29(2):156-160.
[48]李坤宇.无源光纤传像系统传像质量的评价与优化研究[D].南京:南京理工大学博士学位论文,2001,6:1-50.
[49] Israel Gannota, Alon Gorena, Eran Rave, et al. Thermal Imaging through InfraredFiber/Waveguides Bundles[J]. Proc. of SPIE,2004,5317:94-100.
[50]李响,梁中翥,郭鹏,等.光纤传像束研究进展[J].光机电信息,2009,26(7):24-31.
[51] Eran Rave, Abraham Katzir. Ordered bundles of infrared transmitting silver halide fbers:attenuation, resolution and crosstalk in long and fexible bundles[J]. Opt. Eng.,2002,41(7):1467-1468.
[52] M. Yangwn, H. Lin. The crosstalk study of order-packed flexible image bundles[J]. Proc. ofSPIE,1998,3552:232-237.
[53] A. RAY HILTON SR. Infrared imaging bundle development at Amorphous Materials. SPIE,1999,3849:60-66.
[54] M. Saito, M. Takizawa, S. Sakuragi, F. Tanei. Infrared image guide with bundled As-S glassfibers[J]. Appl. Opt.1985,24(15):2304-2319.
[55] A. R. Hilton Sr., A. R. Hilton Jr., J. McCord. Infrared imaging with fiber optic bundles[J].Proc. of SPIE,2003, Vol.5074:849-854.
[56]吕步云,杨克武,薛洪达,等.2m长As-Se-Te玻璃红外光纤传像束[J].红外与激光工程,2001,30(5):357-360.
[57]陈月存.新型工业内窥镜的研究[D].长春:长春理工大学硕士论文,2009,3:20-28.
[58] Dongyuan Li, Lantian Hou, Guiyao Zhou. Design of imaging fber bundle lens with binaryoptical surface[J]. Optical Engineering,2007,46(2):023202-1-5.
[59]李东源,阎秀生,张晓光,等.传像光纤束的折-衍混合耦接器[J].中国激光,2006,33(9):1210-1213.
[60]周胜利.三线阵TDI CCD在测图卫星中的应用分析[J].航天器工程,2007,16(4):19-22.
[61] Liu Xinping, WEN Desheng, QIAO Wei, et al. Subpixel imaging technique[J]. SPIE,1999,3832:158-162.
[62]周峰,王世涛,王怀义.关于亚像元成像技术几个问题的探讨[J].航天返回与遥感,2002,23(4):26-33.
[63]安博文,薛冰玢.光纤耦合的亚像元图像超分辨率重建[J].计算机工程,2012,38(17):222-226.
[64] E. Carrasco, I. R. Parry. A method for determining the focal ratio degradation of optical fibresfor astronomy[J]. Mon. Not. R. Astron., Soc.271.
[65]程欣.大视场光纤成像光谱仪光学系统研究[D].北京:中国科学院研究生院,2012,5:78-90.
[66]张勇,赵达尊.离散成像系统的光学传递函数[J].北京理工大学学报,1997,17(4):151-l55.
[67]王春红,向阳.基于超光谱成像探测系统的线阵CCD的调制传递函数特性研究[J].光谱学与光谱分析,2009,29(6):1478-1481.
[68]李宏升.超光谱成像仪成像链的调制传递函数研究[D].中国科学院长春光学精密机械与物理研究所博士学位论文.2005,12.
[69] Xu He, Yang Xiang. Study on a method of evaluating the alignment of pixels betweenfiber-optic image bundles and detector arrays[J]. Appl. Opt.2011,50(25):189-193.
[70] W Wittenstein, J. C. Fontanella, A. R. Newbery, J. Baars. The definition of the OTF and themeasurement of abasing for sampled imaging system [J]. Opt. Acta,1982,29:41-50.
[71]S. K. Park, R. A. Schowengerdt, M. A. Kaczynski. Modulation-transfer-function analysis forsampled image system[J]. Appl. Opt.1984,23:2572-2582.
[72] RENEE DROUGARD. Optical Transfer Properties of Fiber Bundles[J]. Journal of the opticalsociety of America.1964,54(7):907-915.
[73] L. D. Luca, G Cardone. Modulation transfer function cascade model for a sampled IRimaging system [J]. Appl. Opt.1991,30(13):1659-1664.
[74]金光,钟兴. CCD光学遥感器参数选择研究[J].空间科学学报,2009,29(1):135-139.
[75] M.A. Player. Spread Functions and Modulation Transfer Functions of Fibre-optic Bundles[J].Journal of Modern Optics,1988,35(8):1363-1372.
[76] A. Arefiev, Method for evaluation of fibre optic components MTF[J]. Proc. of SPIE,1995,2507:211-217.
[77] N. S. KAPANY, J. A. EYER, R. E. KEim. Fiber Optics. Part II. Image Transfer on Static andDynamic Scanning with Fiber Bundles[J]. Journal of the optical society of America,1957,47(5):423-427.
[78] K. M. Hock, Effect of oversampling in pixel arrays[J]. Opt. Eng.1995,34:1281-1288.
[79] Hui W, Yang X, and Bingxi Y. Average modulation transfer function of line-array fiber-opticimage bundles[J]. Chin. Opt. Lett.,2(8):453-455.
[80] M. E. Marhic, S. E. Schacham, M. Epstein. Misalignment in imaging multifibers[J]. Appl.Opt.1978,17(21):3503-3506.
[81] J. C. Feltz, M. A. Karim. Modulation transfer function of charge-coupled devices[J]. Appl.Opt.1990,29(5):717-722.
[82]程欣,王晶,张葆,洪永丰.光纤成像光谱仪中谱线畸变对调制传递函数的影响[J].光谱学与光谱分析.2011,31(10):2861-2864.
[83]史光辉.卫星对地观测高分辨率光学系统和设计问题[J].光学精密工程,1999,10(2):16-24.
[84]陈浩锋,李英才,樊超,等.宽视场长焦距离轴三反射镜光学系统的设计[J].光子学报,2007,36(S1):142-145.
[85]王立辉,郁蕴健,陆段军.大线视场大相对口径红外成像系统的光学设计[J].红外与毫米波学报,2008,27(1):39-41.
[86] FISCHER R E, TADIC-GALEB B. Optical System Design[M]. McGraw-Hill,2000:43-47,250-254.
[87]张登臣,郁道银.实用光学设计方法与现代光学系统[M].北京:机械工业出版社,1995.
[88]韩昌元.高分辨力空间相机的光学系统[J].光学精密工程,2008,16(11):2164-2172.
[89]李晓彤,岑兆丰.几何光学·像差·光学设计[M].浙江:浙江大学出版社,2003:208-216.
[90]张鑫,贾宏光,张跃.远距型红外消热差物镜设计[J].红外与激光工程,2012,41(1):78-183.
[91]张以谟.应用光学(第三版)[M].北京:电子工业出版社,2008.
[92]李幼平,禹秉熙,韩昌元,等.成像光谱仪工程权衡优化设计的光学结构[J].光学精密工程,2006,14(6):974-979.
[93]丛杉珊.大视场长焦距反射式空间光学系统设计[D].长春:长春理工大学,2008:3-8.
[94]宫广彪.超光谱成像仪前置成像物镜设计[D].苏州:苏州大学硕士学位论文,2009,4:8-9.
[95]史黎丽.航天遥感相机光学系统设计研究[D].哈尔滨:哈尔滨工业大学工学硕士学位论文.2007,7:13-17.
[96] https://directory.eoportal.org/web/eoportal/satellite-missions/c-missions/cartosat-2b
[97] Marc Postman, Tom Brown, Kenneth, et al. Sembach Advanced Technology Large-ApertureSpace Telescope: science drivers and technology developments[J]. Optical Engineering,2012,51(1):011007-1-11.
[98] Jun-ichi Ishigakia, Toshihiro Okamuraa, Kunihiro Tanikawaa. Designing and Testing ofOff-axis Three-Mirror Optical System for Multi-Spectral Sensor[J]. SPIE,3061:356-369.
[99]宋岩峰,邵晓鹏,徐军.离轴三反射镜光学系统研究[J].红外与激光工程,2008,37(4):706-709.
[100]潘君骅.光学非球面的设计、加工与检验[M].苏州:苏州大学出版社,2004:21-37,130-141.
[101]杨建峰,安葆青,薛鸣球.大视场三反射面非共轴光学系统研究[J].光子学报,1997,26(3):277-281.
[102]常军,翁志成,姜会林,等.长焦距空间三反光学系统的设计[J].光学精密工程,2001,9(4):315-318.
[103] BRCT-DIBAT T, ALBOUYS V, BERTHON J, et al.. Yest of a high resolution three mirroranastigmat telescope [J]. SPIE,2000,3870:128-137.
[104]金光,张亮,胡福生.大F数高分辨率空间望远镜光学系统[J].光学精密工程,2007,15(2):155-159.
[105]李旭阳,李英才,马臻,易红伟.高分辨率空间相机共轴三反光学系统实现形式研究[J].应用光学,2009,30(5):717-723.
[106] Michael. Lidwell. Mirror telescope for long linear detector arrays[J]. SPIE,1998,3429:19-30.
[107]杨秉新.美国IKONOS和QuickBird2卫星相机的主要性能和特点分析及看法[J].航天返回与遥感,2002,23(4):10-12.
[108] Pleiades Programme Overview[M]. Presentation of SPOT IMAGE Direct Receiving StationMeeting,2006.
[109] LAMPTON M L, SHOLL M J. Comparison of on-axis three-mirror-anastigmat telescopes[J].SPIE,2007,6687:66870S-1-8.
[110]张科科,阮宁娟,傅丹鹰.国外空间用三反离轴相机发展分析与思考[J].航天返回与遥感,2008,29(3):63-70.
[111] Roland GEYL. Design and fabrication of a Three Mirror Flat Field Anastigmat for highresolution earth observation[J]. SPIE,2210:739-746.
[112] FIGOSKI J W. Development of three-mirror wide-field sensor from paper design tohardware[J].SPIE,1989,1113:126-133.
[113]陈浩峰.用于空间相机的离轴反射式光学系统研究[D].北京:中国科学院研究生院硕士学位论文,2007,7:14-16.
[114]刘晓梅,向阳.宽视场成像光谱仪前置远心离轴三反光学系统设计[J].光学学报,2011,31(6):0622004-1-4.
[115] Joey Espejo, Ginger Drake, Karl Heuerman, et al.. A hyperspectral imager for highradiometric accuracy Earth climate studies[J]. Proc. of SPIE,8158:81580B-1-9.
[116]刘晓梅,向阳.具有实入瞳的远心离轴三反系统研究与设计[J].光学学报,2011,31(11):1122002-1-4.
[117]王美钦,王忠厚,白加光.成像光谱仪的离轴反射式光学系统设计[J].红外与激光工程,2012,41(1):167-172.
[118] W. B. Wetherell. Image quality criteria for the large space telescope[C]. NationalAcademy of Sciences, Washington, D.C.,1974.55-103.
[119]李欢,向阳.10°远心离轴三反消象散望远系统的光学设计[J].光子学报,2009,38(9):2256-2259.
[120]薛庆生,黄煜,林冠宇.大视场高分辨力星载成像光谱仪光学系统设计[J].光学学报,2011,31(8):0822001-1-6.
[121]刘新平,杨建峰.折轴三反射镜成象光学系统结构研究[J].光子学报,1998,27(1):73-76.
[122] Joseph M. Geary. Introduction to lens design with practical ZEMAX example. USA Virginia:Willmann-Bell,Inc.2002.
[123] R. Barry Johnson. Wide field of view three-mirror telescope having a common opticalaxis[J]. Opt.Eng,1988,27(12):1046-1050.
[124]郭永祥,李英才,梁天梅,等.一种大视场离轴三反射光学系统研究[J].光学学报,2010,30(9):2680-2683.
[125] Kunihiro Tanikawa, Toshihiro Okamura, Jun-ichi Kudo, Hideo Wada, Hiromichi Shirahata.Six band multispectral sensor using off-axis three-mirror reflective optics[J]. Opt. Eng.2000,39(10):2781-2788.
[126] Anna-Britt Mahler, Russell Chipman. Tolerancing and alignment of a three-mirror off-axistelescope[J]. Proc. of SPIE,6676:66760I-1-8.
[127]杨晓飞,韩昌元.利用离轴三反镜光学系统确定各镜的装调公差[J].光学技术,2005,31(2):173-176.
[128]张登臣,郁道银.实用光学设计方法与现代光学系统[M].北京:机械工业出版社,1995.
[129]杨晓飞,张晓辉,韩昌元. ZEMAX软件在离轴三反射镜系统计算机辅助装调中的应用[J].光学精密工程,2004,12(3):270-274.
[130] Allen mann.Infrared optics and zoom lenses[M]. SPIE.2009.
[131]赵秀丽.红外光学系统设计[M].北京:机械工业出版社,1986.
[132]杨福兴.非球面光学零件的超精密磨削技术[J].机械工艺师,1998,6:13-14.
[133]温午麒,康建翊,丁欣,等.用非球面透镜制作光纤的1:1空间耦合器[J].光子学报,2012,41(3):294-298.
[134]宋岩峰.现代红外光学系统设计[D].西安:西安电子科技大学硕士学位论文,2008,1:11-20.
[135]刘玉娟,唐玉国,崔继承,巴音贺希格,齐向东.红外成像光谱测量中Dyson光学系统的研究进展[J].光谱学与光谱分析,2012,32(2):548-552.
[136]付强,黄旻,景娟娟,相里斌.用于液晶可调谐滤光片型多光谱成像仪的中继成像系统设计[J].光学学报,2011,31(10):10220021-10220025.
[137]沈为民,薛鸣球,余建军.大视场大相对孔径长波红外物镜[J].光子学报,2004,4:460-463.
[138]沈为民,薛鸣球,余建军.长波红外广角地平仪镜头的光学设计[J].光学精密工程,2002,8:329-332.
[139]杨胜杰.高分辨率制冷型中波广角红外成像系统的光学设计[J].光学学报,2002,8:08220031-08220036.
[140]向鹏飞,李贝,袁安波.一种新的微透镜阵列制作技术[J].半导体光电,2012,33(2):197-200.
[141] Masaharu Deguchi, Takesuke Maruyama, Futoshi Yamasaki. Microlens design usingsimulation for CCD image sensor[J]. IEEE Transactions on Consumer Electronics,1992,38(3):583-589.
[142]吴振华,易新建,麦志洪等. IRCCD微透镜阵列的计算机模拟设计与分析[J].光电子2激光,1998,9(2):110-112.
[143]孙艳军,冷雁冰,陈哲,董连和.用于红外焦平面的正方形孔径球面微透镜阵列研究[J].光子学报,2012,41(4):399-403.
[144]孙艳军,冷雁冰,陈哲,董连和.硅基自由曲面光学微透镜阵列制作的光学性能研究[J].红外技术,2012,34(1):44-47.
[145] Deqing Ren, Jeremy Allington-Smith, Ray Sharples, George Dodsworth. The design andconstruction of a Multiple-Integral-Field-Unit for8-meter Telescopes[J]. Proceedings of SPIE Vol.4842,2003,384-391.
[146] Ren Yang, Steven A. Soper, Wanjun Wang. Microfabrication of pre-aligned fber bundlecouplers using ultraviolet lithography of SU-8[J]. Sensors and Actuators A,2006,(127):123-130.
[147] Ian R. Parry. Optical fbres for integral feld spectroscopy[J]. New Astronomy Reviews,2006,50:301-304.
[148] Daniel V. Hahn, David M. Brown, Nathan W. Rolander, et al.. Fiber optic bundle array widefield-of-view optical receiver for free space optical communications[J]. OPTICS LETTERS,2010,35,(21):3559-3561.
[149] Andrea M. Brown, Daniel V. Hahn, David M. Brown, et al.. Experimental implementation offiber optic bundle array wide FOV free space optical communications receiver[J]. APPLIEDOPTICS,2012,51(18):3995-4002.
[150]阎嫦玲,鲁平,刘德明,等.与光纤阵列耦合的微透镜阵列设计与损耗分析[J].光电子·激光,2006,17(9):1044-1047.
[151]李佳.用于传像光纤束集成的折射微透镜阵列研究[D].武汉:华中科技大学,2008:24-46.
[152] Haynes Dionne M, Withford Michael J, Dawes Judith M, et al. Focal ratio degradation: Anew perspective[J]. Proc. of SPIE,2008,7018.
[153]王森,朱冰.大芯径光谱传光光纤焦比退化特性研究.光电工程,2011,38(7):17-24.
[154]董艳,朱冰. LAMOST传光光纤的焦比退化特性分析[J].中国科学技术大学学报,2007,37(6):606-611.
[155] Murphy J D, MacQueen P J. Focal Ratio Degradation and Transmission in VIRUS-P OpticalFibers[J]. Pro. of SPIE,2008,7018:70182T.1-70182T.12.
[156] Gerardo Avila, Paul Singh, Maja Albertsen. Photometrical scrambling gain and focal ratiodegradation in fibers for astronomical instruments[J]. Pro. of SPIE,2006,6269:626950-1-9.
[157] S. Arribas, E. Mediavilla. Integral field spectroscopy with optical fibers: studies of thecircumnuclear regions of nearby active galactic nuclei[J]. ASP conference series,2000,195:295-306.
[158] Ramsey Lawrence W. Focal ratio degradation in optical fibers of astronomical interest[J].Astronomical Society of the Pacific,1988,3:26-39.
[159]柯才军.微透镜阵列的设计、制作及与CCD的集成技术[D].武汉:华中科技大学博士学位论文,2005,4:8-12.
[160]张玉.六角形孔径平面微透镜阵列研究[D].重庆:西南大学硕士学位论文,2007,4:10-11.
[161]刘德森.微透镜阵列与微小光学[J].光子学报.1994,23(z2):67-76.
[162]马相路.光纤传像束原理及其应用[J].光机电信息,2007,24(10):44-49.
[163]任智斌,朱丽思,曾皓,姜会林.微透镜阵列的光刻胶热熔制作技术[J].长春理工大学学报,2006,12:15-20.
[164] Z D Popovic, R A Spague, G A Neville Connell. Techniques for Monolithic Fabrication ofMicrolens Arrays. Applied Optics,1988,27:1281-1284.
[165]张新宇,易新建,何苗,赵兴荣.面阵IRCCD摄像芯片用折射微透镜阵列的离子束刻蚀制作[J].电子学报,1999,27(8):135-136.
[166] ZHANG Feng-jun, ZHOU Su-mei, JIANG Xiao-ping, Liu De-sen. Fabrication of PlanarSquare Aperture Microlens Array. ACTA PHOTONICA SINICA,2008,37(S2):202-203.
[167] ZHANG Xinyu, YI Xinjian, HE Miao, ZHAO Xingrong. Large-area Quartz Glass MicrolensArray Fabricated by lon Beam Etching for Focal Plane Detectors[J]. J. Infrared Millim.Waves,1999,18(2):97-105.
[168]麦志洪,易新建,赵兴荣,郝建华.用于红外焦平面的微透镜阵列单片制备技术[J].华中理工大学学报,1996,24(7):77-79.
[169]任智斌,卢振武.通过缩短显影时间提高微透镜阵列的填充因子与F数[J].光电子·激光,2005,16(2):150-154.
[170]刘德森,高应俊.微小光学与微小光子器件[J].光子学报,1997,26(Z1):21-27.
[171]于双双.微透镜阵列光学耦合扩束技术研究[D].哈尔滨:哈尔滨工业大学,2011,6.
[172]刘德森,蒋小平.微小光学与异形孔径微透镜阵列研究[J].激光与光电子学进展,2010,47,083501-1-16.
[173] XIANG Peng-fei, LI Bei, YUAN An-bo. New fabrication technology of Microlens array[J].Semiconductor Optoelecronics,2012,33(2):197-200.