留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

临近空间平台光电探测系统在空间态势感知中的应用

徐蓉 门涛 张荣之

徐蓉, 门涛, 张荣之. 临近空间平台光电探测系统在空间态势感知中的应用[J]. 中国光学(中英文), 2010, 3(6): 546-553.
引用本文: 徐蓉, 门涛, 张荣之. 临近空间平台光电探测系统在空间态势感知中的应用[J]. 中国光学(中英文), 2010, 3(6): 546-553.
XU Rong, MEN Tao, ZHANG Rong-zhi. Application of near space platform based photoelectric detecting system to space situation awareness[J]. Chinese Optics, 2010, 3(6): 546-553.
Citation: XU Rong, MEN Tao, ZHANG Rong-zhi. Application of near space platform based photoelectric detecting system to space situation awareness[J]. Chinese Optics, 2010, 3(6): 546-553.

临近空间平台光电探测系统在空间态势感知中的应用

详细信息
  • 中图分类号: V11

Application of near space platform based photoelectric detecting system to space situation awareness

  • 摘要: 介绍了空间态势感知的概念,以及地基、天基光电探测系统和临近空间平台的特点及研究现状,对不同平台光电探测系统的性能与特点进行了分析。分析表明,地基光电探测系统的观测质量受地球大气湍流和大气吸收的影响,有其极限探测能力,且大部分大气扰动发生在大气最底层的对流层;天基光电探测系统虽然可不受大气湍流的扰动,但光电探测平台的探测时间只有地基望远镜的1/3,且耗资巨大;临近空间平流层平台(飞艇)光电探测系统不受对流层大气扰动的影响,其分辨力可显著提高,并且具有灵活布站等优势。基于临近平台光电探测系统的优势,综述了发展临近平台空间光电探测系统的可行性,归纳总结了将其应用于空间态势感知的技术要求,涉及材料、控制、能源和高能物理等。

     

  • [1] 高琳,刘贺军,宋耀东. 美国空间攻防装备发展现状和趋势[J]. 电光系统 ,2009(2):43-46. GAO L,LIU H J,SONG Y D. Present status and development trends of space attack and defense equipment of USA[J]. Electronic and Electro-optical Systems,2009(2):43-46.(in Chinese) [2] FUGATE R Q. The starfire optical range 3.5-m adaptive optical telescope[J]. SPIE,2003,4837:934-943. [3] 姜文汉. 自适应光学技术[J]. 自然杂志 ,2006(1):7-13. JIANG W H. Adaptive optical technology[J]. Chinese J. Nature,2006(1):7-13.(in Chinese) [4] 吴鑫基,温学诗.现代天文学十五讲[M]. 北京:北京大学出版社, 2005. WU X J,WEN X SH. Fifteen Prelection of Modern Astronomy[M]. Beijing:Peking University Press,2005.(in Chinese) [5] 张逸新,迟泽英.光波在大气中的传输与成像 [M]. 北京:国防工业出版社,2005. ZHANG Y X,CHI Z Y. The Transmission of Light in the Atmosphere and Imaging[M]. Beijing:National Defence Industry Press,2005.(in Chinese) [6] HARRISON D C,CHOW J C. Space-based visible sensor on MSX satellite[J]. SPIE,1994,2217:377-387. [7] STOKES G H,von BRAUN C,STRIDHARAN R. The space-based visible program[J]. Lincoln Laboratory J.,1998,11:205-238. [8] ANDREAS J E. Space-based Infrared System(SBIRS) system of systems[J]. IEEE,1997,5:429-438. [9] WU A. SBIRS high payload LOS attitude determination and calibration[J]. IEEE,1998,5:243-253. [10] SLATTERY J E,COOLEY P R. Space-based Infrared Satellite System(SBIRS) requirements management[J]. IEEE,1998,5:223-232. [11] GARNHOLZ D B. A proposal for a large-aperture, airship-mounted, stratospheric telescope . 12th Lighter-Than-Air Systems Technology Conference.San Francisco,USA,June 1997:1-11. [12] BERNASCONI P N,RUST D M,EATON H A,et al. A ballon-borne telescope for high resolution solar imaging and polarimetry[J]. SPIE,2000,4014:214-225. [13] JONATHAN McD. Mission update[J]. Sky & Telescope,1999,98(4):16-24. [14] BECKLIN E E,GEHRZ R D. Stratospheric Observatory for Infrared Astronomy(SOFIA)[J]. SPIE,2009,7453:1-12. [15] GULL G E,SAVAGE M L. An introduction to airworthiness for science instruments onboard SOFIA[J]. SPIE,2000,4014:183-194. [16] ERDMANN M,BITTNER H,HABERLER P. Development and construction of the optical system for the airborne observatory SOFIA[J]. SPIE,2000,4014:306-318. [17] LEE M,SMITH S,ANDROULAKAKIS S. The high altitude Lighter Than Air Airship Efforts at the US Army Space and missile defense command/army force strategic command . 18th AIAA Lighter-Than-Air Systems Technology Conference,Seattle,USA,4-7 May 2009:1-26. [18] ONDA M. Design considerations on stratospheric long endurance LTA platform . 13th AIAA,Lighter-Than-Air Systems Technology Conference,June 1999:204-209.
  • 加载中
计量
  • 文章访问数:  5016
  • HTML全文浏览量:  584
  • PDF下载量:  3361
  • 被引次数: 0
出版历程
  • 收稿日期:  2010-05-11
  • 修回日期:  2010-08-13
  • 刊出日期:  2010-12-20

目录

    /

    返回文章
    返回