[1] [1] ZHOU Liwei. Target detection recognition[M]. Beijing: Beijing Institute of Technology Press, 2004.

[2] [2] HU Wenming. UAS technology[M]. Beijing: National Defence Industry Press, 2009.

[3] [3] GERALD C H. Electrooptical imaging system perfmance[M]. 4th ed. Translated by YAN Jixiang, YU Xin, XIE Tianbao, et al. Beijing: National Defence Industry Press, 2015.

[4] [4] ZHOU Shichun. Introduction to advanced infrared optoelectronic engineering[M]. Beijing: Science Press, 2014.

[5] [5] XIANG Shiming, GAO Jiaobo, JIAO Mingyin, et al. Introduction to modern photoelectron imaging technology[M]. Beijing: Beijing Institute of Technology Press, 2010.

[6] [6] WANG Yuxiang, LIU Zaozhen, HU Jinglin. Guided bomb[M]. Beijing: dnance Industry Press, 2006.

[7] SHEN Honghai, HUANG Meng, LI Jiaquan, . Recent progress in aerial electro-optic payloads and their key technologies[J]. Chinese Optics, 5, 20-29(2012).

[8] JI Shupeng. Equipment development of airborne electro-optic payload and its key technologies[J]. Aero Weaponry, 24, 3-12(2017).

[9] ZHANG Weiwei, ZHANG Qiuli, ZHANG Qian, . Research achievements and development trends of imaging system with wide area persistent surveillance[J]. Journal of Applied Optics, 35, 111-115(2014).

[10] LI Yongkun, LIN Zhaorong, ZHANG Xuguo. Development survey of foreign aerial cameras for distant oblique reconnaissance[J]. Spacecraft Recovery & Remote Sensing, 38, 11-18(2017).

[11] [11] WU Hanping. Infrared search system[M]. Beijing: National Defence Industry Press, 2013.

[12] [12] LIU Jingjiao. Photoelectric countermeasure technology system[M]. Beijing: Science Technology of China Press, 2004.

[13] ZHANG Weiguo, PANG Lan, TAO Zhong, . Discussion on development trend of airborne opto-electronic aiming system[J]. Journal of Applied Optics, 40, 16-21(2019).

[14] HUANG Jun, ZHANG Zhengyong, TIAN Shengmin. Current status and development trend of airborne air to ground electro-optical detection equipment[J]. Infrared Technology, 40, 412-416(2018).

[15] JIA Ping, ZHANG Bao. Critical technologies and their development for airborne opto-electronic reconnaissance platforms[J]. Optics and Precision Engineering, 11, 82-88(2003).

[16] HONG Huajie, WANG Xuewu, WENG Ganfei. Mirror stabilization in electro-optical reconnaissance system[J]. Journal of Applied Optics, 32, 591-597(2011).

[17] WANG Zhen, CHENG Xuemin. Research progress and development trend of fast steering mirror[J]. Journal of Applied Optics, 40, 373-379(2019).

[18] XU Feifei, LIU Sha, YIN Mingdong, . Performance comparison and analysis of coarse and fine combined stabilization control system based on mirror compensation[J]. Journal of Applied Optics, 34, 15-20(2013).

[19] GILMORE J P, LUNIEWICZ M F, SARGENT D. Enhanced precision pointing jitter suppression system[J]. SPIE, 4632, 38-49(2002).

[20] WANG Dazhi, FAN Yue. Design of flexible support for fast steering mirror via kinematic principles[J]. Journal of Applied Optics, 42, 413-417(2021).

[21] WEI Wenjun, ZHAO Xuetong. Application of sliding mode dynamic surface control in fast steering mirror[J]. Journal of Applied Optics, 39, 714-721(2018).

[22] [22] HAN Chongzhao, ZHU Hongyan, DUAN Zhansheng, et al. Multisource infmation fusion[M]. 2nd ed. Beijing: Tsinghua University Press, 2010.

[23] CHEN Jian, WANG Weiguo, LIU Tingxia, . The operational principle analysis of new airborne electro-optical targeting system (EOTS) of US army[J]. Chinese Optics, 10, 777-782(2017).

[24] WANG Fangyu. Electric-optic load and development analysis of the American UAV[J]. Laser & Infrared, 38, 311-314(2008).