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分时偏振成像系统中光束偏离的补偿方法研究

侯俊峰 吴太夏 王东光 邓元勇 张志勇 孙英姿

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分时偏振成像系统中光束偏离的补偿方法研究

侯俊峰, 吴太夏, 王东光, 邓元勇, 张志勇, 孙英姿

Study on compensation method of beam deviation in division of time imaging polarimetry

Hou Jun-Feng, Wu Tai-Xia, Wang Dong-Guang, Deng Yuan-Yong, Zhang Zhi-Yong, Sun Ying-Zi
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  • 分时偏振成像系统需要通过旋转检偏器获取场景的偏振信息(I, Q, U), 检偏器的前后表面间不平行(也称为楔角)将导致成像光束发生偏离且随检偏器旋转而旋转, 这将降低偏振成像系统的空间分辨率和偏振测量精度. 本文提出调整检偏器相对于入射主光轴倾斜角的方法来补偿上述光束偏离. 以格兰棱镜作为检偏器, 根据几何光学理论, 推导了分时偏振成像系统光束偏离的一阶近似补偿模型, 获得倾斜角与格兰棱镜楔角之间的函数关系, 并通过仿真模拟验证了该补偿方法的可行性和有效性. 研究结果表明, 将格兰棱镜置于汇聚光路中, 光束偏离的一阶误差可以通过调节格兰棱镜的倾斜角有效补偿; 倾斜角大小与棱镜折射率、楔角及棱镜距电荷耦合元件靶面的距离成正比, 与棱镜厚度成反比. 该结果为研制高精度分时偏振成像系统提供了切实可行的理论依据.
    In the division of time imaging polarimetry, polarization information of field under measurement (I, Q, U), is obtained by rotating the analyzer. In the process of measurement, the beam deviation caused by the wedge of the analyzer reduces the spatial resolution and polarization accuracy of imaging polarimetry. In this paper we present that the beam deviation above can be reduced or even compensated for by adjusting the tilt angle of analyzer with respect to the incident optical axis. Taking Glan prism as the analyzer, we establish the first-order approximate compensation model of beam deviation based on the theory of geometric optics, acquiring the function relation between the tilt angle and wedge of Glan prism, and verify the feasibility and effectiveness of the compensation method by simulation. The study shows that the first-order approximation error of beam deviation can be compensated for by adjusting the tilt angle of Glan prism if only Glan prism is placed in a convergent beam; the tilt angle is proportional to Glan prism wedge angle, refractive index, and distance to CCD, but inversely proportional to Glan prism thickness. The results provide a theoretical basis for developing the time division imaging polarimetry with high spatial resolution and polarization accuracy.
    • 基金项目: 国家自然科学基金(批准号: 11403047, 11178005, 11373044, 11273034, 11373042)资助的课题.
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 11403047, 11178005, 11373044, 11273034, 11373042).
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    [31]

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    Beck C, Schmidt W, Kentischer T, Elmore D 2005 A&A 437 1159

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    Snik F 2006 SPIE 6269 62695

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    Liu J, Xia R Q, Jin W Q, Wang X, Du L 2013 Opt. Tech. 39 56 (in Chinese) [刘敬, 夏润秋, 金伟其, 王霞, 杜岚 2013 光学技术 39 56]

  • [1]

    Egan W G 1992 SPIE 1747 128

    [2]

    Tyo J S, Goldstein D H, Chenault D B, Shaw J A 2006 Appl. Opt. 45 5451

    [3]

    Talmage D A, Curran P J 1986 Int. J. Remote Sensing 7 47

    [4]

    Breon F M, Tanre D, Lecomte P, Herman M 1995 TGARS 33 487

    [5]

    Wu T, Zhao Y 2005 TGARS 43 2854

    [6]

    Xie D H, Gu X F, Cheng T H, Yu T, Li Z Q, Chen X F, Chen H, Guo J 2012 Acta Phys. Sin. 61 077801 (in Chinese) [谢东海, 顾行发, 程天海, 余涛, 李正强, 陈兴峰, 陈好, 郭婧 2012 物理学报 61 077801]

    [7]

    Harchanko J S, Chenault D B 2002 SPIE 6240 58881511

    [8]

    Zappa C J, Banner M L, Schultz H, Emmanuel A C, Wolff L B, Yalcin J 2008 Meas. Sci. Technol. 19 0555031

    [9]

    Liang S Y, Wang J A, Zong S G, Wu R H, Ma Z G, Wang X Y, Wang L D 2013 Acta Phys. Sin. 62 060704 (in Chinese) [梁善勇, 王江安, 宗思光, 吴荣华, 马治国, 王晓宇, 王乐东 2013 物理学报 62 060704]

    [10]

    Pezzaniti J L, Chenault D, Roche M, Reinhardt John, Schultz H 2009 SPIE 7317 73170B1

    [11]

    Liu G L, Li Y F, Cameron B D 2002 SPIE 4617 208

    [12]

    Wen Q, Wang K G, Shao Y H, Qu J L, Niu H B 2013 Acta Phys. Sin. 62 034203 (in Chinese) [文侨, 王凯歌, 邵永红, 屈军乐, 牛憨笨 2013 物理学报 62 034203]

    [13]

    Smith M H, Paul D B, Lompado A, Tanner E A, Hillman L W 2000 SPIE 3911 210

    [14]

    Hansen J E, Travis L D 1974 Space Sci. Rev. 16 527

    [15]

    Zhao X F, Huang S X, Xiang J, Shi W L 2011 Chin. Phys. B 20 099201

    [16]

    Zeng J, Han Q, Wang J 2008 Geo. Res. Lett. 35 20801

    [17]

    Cheng S Y, Xu L, Gao M G, Li S, Jin L, Tong J J, Wei X L, Liu J G, Liu W Q 2013 Chin. Phys. B 22 129201

    [18]

    Geyer E H, Jockers K, Kiselev N N, Chernova G P 1996 Astrophy. Space Sci. 239 259

    [19]

    Kawabata K S 2008 SPIE 7014 70144L1

    [20]

    Bailey J, Chrysostomou A, Hough J H, Gledhill T M, McCall A, Clark S, Ménard F, Tamura M 1998 Science 281 672

    [21]

    Donati J F, Paletou F, Bouvier J, Ferreira J 2005 Nature 438 466

    [22]

    Hough J H 2005 ASP 343 3

    [23]

    Vink J S, Harries, T J, Drew, J E 2005 A&A 430 213

    [24]

    Diner D J, Chipman R A, Beaudey N, Cairns B, Foo L D, Macenka S A, Cunningham T J, Seshadri S, Keller C U 2005 SPIE 5659 88

    [25]

    Ichimoto K 2008 Solar Phys. 249 233

    [26]

    Ambirajan A, Look D C 1995 Opt. Eng. 34 1651

    [27]

    Ambirajan A, Look D C 1995 Opt. Eng. 34 1656

    [28]

    Sabatke D S, Descour M R, Dereniak E, Sweatt W C, Kemme S A, Phipps G S 2000 Opt. Lett. 25 802

    [29]

    Tyo J S 2000 Opt. Lett. 25 1198

    [30]

    Tyo J S 2002 Appl. Opt. 41 619

    [31]

    Chen L G, Meng F G, Yuan Y L, Zheng X B 2010 J. Atmosph. Environ. Opt. 5 227 (in Chinese) [陈立刚, 孟凡刚, 袁银麟, 郑小兵 2010 大气与环境光学学报 5 227]

    [32]

    Azzam R M A, Lopez A G 1989 J. Opt. Soc. Am. A 6 1513

    [33]

    Wang Y H, Zheng C L, Zhao Z T 2012 Chin. J. Lasers 39 1108013 (in Chinese) [王勇辉, 郑春龙, 赵振堂 2012 中国激光 39 1108013]

    [34]

    Hou J F, Wang D G, Deng Y Y, Zhang Z Y, Sun Y Z 2013 Opt. Precision Engineer. 21 1915 (in Chinese) [侯俊峰, 王东光, 邓元勇, 张志勇, 孙英姿 2013 光学精密工程 21 1915]

    [35]

    Beck C, Schmidt W, Kentischer T, Elmore D 2005 A&A 437 1159

    [36]

    Snik F 2006 SPIE 6269 62695

    [37]

    Liu J, Xia R Q, Jin W Q, Wang X, Du L 2013 Opt. Tech. 39 56 (in Chinese) [刘敬, 夏润秋, 金伟其, 王霞, 杜岚 2013 光学技术 39 56]

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出版历程
  • 收稿日期:  2014-08-16
  • 修回日期:  2014-10-15
  • 刊出日期:  2015-03-05

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