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摘要: 利用平面反射镜进行光路折转以减小航空遥感器体积及质量是一种常用设计手段,而平面反射镜的引入对航空遥感器的装调工作提出了更高的要求。为此本文提出了一种用于航空遥感器平面反射镜系统的装调方法。利用坐标变换法建立经纬仪测量数学模型,推导出单个平面反射镜组件及平面反射镜系统角度偏差(俯仰偏差及方位偏差)与经纬仪测量值之间的对应关系。提出了利用经纬仪完成平面反射镜系统角度偏差测量及装调的方法。最终使镜头光轴与焦平面安装面法线的俯仰偏差和方位偏差均满足不大于2′的指标要求。应用该方法已完成10余套航空遥感器反射镜系统的装调,方法方便高效。同时,该方法可为各种光学仪器中平面反射镜角度标定及装调提供解决思路。Abstract: It is a common design method to reduce the volume and mass of aerial remote sensors by using the plane mirror to replace the light path. However, the introduction of a plane mirror puts forward stricter requirements for the alignment of the aerial remote sensor. We propose an alignment method for the plane mirror system of an aerial remote sensor. The mathematical model of the theodolite measurement is established by the coordinate transformation method, and the corresponding relationship between the angular deviation (pitch deviation and azimuth deviation) of the single plane mirror assembly and plane mirror system and the measured value of the theodolite is deduced. Then a method of measuring and adjusting the angle deviation of the plane mirror system with theodolite is proposed. Finally, the pitch angle deviation and azimuth angle deviation between the lens optical axis and the normal of the focal plane mounting surface meet the index requirements of being no more than 2′. More than 10 sets of aerial remote sensor plane mirror systems have been aligned using this method, which is both convenient and efficient. At the same time, this method can provide a solution for the angle calibration and alignment of the plane mirror in various optical instruments.
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Key words:
- aerial remote sensor /
- reflecting mirror /
- angle deviation /
- alignment /
- calibration
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图 4 单个反射镜组件角度偏差测量示意图
Figure 4. Schematic diagram of the angle deviation measurement of a single reflector assembly
图 5 单个反射镜组件测量坐标系建立
Figure 5. Establishment of measurement coordinate systems for the single reflector assembly
图 6 角度β经纬仪测量误差的计算结果(计算次数为100万次)
Figure 6. Calculation results of the theodolite measurement error for angle β ( 1 million calculation times)
图 7 反射镜系统测量坐标系建立
Figure 7. Establishment of the measurement coordinate systems for the plane reflecting mirror system
图 8 (a)方位偏差p和(b)俯仰偏差q近似值误差的计算结果(计算次数为100万次)
Figure 8. Calculation results of the approximate error of (a) the azimuth angle deviation p and (b) the pitching angle deviation q ( 1 million calculation times)
图 9 反射镜组件1装调示意图
Figure 9. Schematic diagram of the alignment of the first reflector assembly
图 10 反射镜组件3装调示意图
Figure 10. Schematic diagram of the alignment of the third reflector assembly
图 11 反射镜组件2装调示意图
Figure 11. Schematic diagram of the alignment of the second reflector assembly
表 1 10套航空遥感器反射镜系统装调结果
Table 1. Alignment results of the angle deviation of the reflector system of 10 aerial remote sensors
序号 俯仰偏差 方位偏差 1 50″ 10″ 2 63″ 1″ 3 43″ 1″ 4 63″ 10″ 5 55″ 1″ 6 17″ 4″ 7 56″ 2.3″ 8 10″ 11″ 9 49″ 15″ 10 59″ 11″ 
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[1] 张健. 全景式航空遥感器焦平面组件TDI方向标定方法研究[D]. 长春: 中国科学院大学(中国科学院长春光学精密机械与物理研究所), 2018.ZHANG J. Research on calibration method of TDI direction for focal plane assembly in aerial panoramic camera[D]. Changchun: University of Chinese Academy of Sciences (Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences), 2018. (in Chinese) [2] MILLER J L, WAY S P, ELLISON B, et al. Design challenges regarding high-definition electro-optic/infrared stabilized imaging systems[J]. Optical Engineering, 2013, 52(6): 061310. doi: 10.1117/1.OE.52.6.061310 [3] 李军, 黄厚田, 修吉宏, 等. 载机飞行参数对倾斜成像重叠率影响及补偿[J]. 光学 精密工程,2020,28(6):1254-1264. doi: 10.3788/OPE.20202806.1254LI J, HUANG H T, XIU J H, et al. Effect and compensation of overlap influenced by flight parameter of oblique aerial camera[J]. Optics and Precision Engineering, 2020, 28(6): 1254-1264. (in Chinese) doi: 10.3788/OPE.20202806.1254 [4] 李大伟. 长焦距航空遥感器的光学装调[J]. 长春理工大学学报(自然科学版),2012,35(2):29-32.LI D W. Optical alignment of long focus aerial camera[J]. Journal of Changchun University of Science and Technology (Natural Science Edition) , 2012, 35(2): 29-32. (in Chinese) [5] 张继超, 李大伟. 长焦距光学系统中反射光路的设计与装调[J]. 红外与激光工程,2015,44(5):1496-1499.ZHANG J CH, LI D W. Design and adjustment of the reflection optical path in a long optical system[J]. Infrared and Laser Engineering, 2015, 44(5): 1496-1499. (in Chinese) [6] 王旻, 余毅, 王春霞. 折转光管在光电瞄准系统中的应用[J]. 中国光学,2012,5(6):618-624.WANG M, YU Y, WANG CH X. Application of reflex light-tube to photoelectric pointing system[J]. Chinese Optics, 2012, 5(6): 618-624. (in Chinese) [7] 王家骐, 于平, 颜昌翔, 等. 航天光学遥感器像移速度矢计算数学模型[J]. 光学学报,2004,24(12):1585-1589.WANG J Q, YU P, YAN CH X, et al. Space optical remote sensor image motion velocity vector computational modeling[J]. Acta Optica Sinica, 2004, 24(12): 1585-1589. (in Chinese) [8] 颜昌翔, 王家骐. 航相机像移补偿计算的坐标变换方法[J]. 光学 精密工程,2000,8(3):203-207.YAN CH X, WANG J Q. Method of coordinate transformation for IM & IMC calculation in aerospace camera system[J]. Optics and Precision Engineering, 2000, 8(3): 203-207. (in Chinese) [9] 李斌, 陈佳夷, 王海超, 等. 卡塞格林系统装调过程中高精度测角方法[J]. 应用光学,2017,38(6):958-962.LI B, CHEN J Y, WANG H CH, et al. Accuracy angular measurement method in alignment process for Cassegrain telescope[J]. Journal of Applied Optics, 2017, 38(6): 958-962. (in Chinese) [10] 张赢, 丁红昌, 赵长福, 等. 基于多激光传感器装配的自由曲面法线找正方法研究[J]. 中国光学,2021,14(2):344-352. doi: 10.37188/CO.2020-0205ZHANG Y, DING H CH, ZHAO CH F, et al. The normal alignment method for freeform surfaces based on multiple laser sensor assembly[J]. Chinese Optics, 2021, 14(2): 344-352. (in Chinese) doi: 10.37188/CO.2020-0205 [11] 田海英, 惠守文, 李友一, 等. 用作图法判定航空相机TDI CCD积分方向[J]. 光学 精密工程,2007,15(11):1784-1788.TIAN H Y, HUI SH W, LI Y Y, et al. Estimation of TDI direction of CCD sensor in aerial camera by graphing method[J]. Optics and Precision Engineering, 2007, 15(11): 1784-1788. (in Chinese) [12] SCHWERTZ K, BURGE J H. Field Guide to Optomechanical Design and Analysis[M]. Washington: SPIE, 2012: 10-11. [13] 费业泰. 误差理论与数据处理[M]. 6版. 北京: 机械工业出版社, 2010.FEI Y T. Error Theory and Data Processing[M]. 6th ed. Beijing: China Machine Press, 2010. (in Chinese) -
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