[1] Chenghao ZHOU, Zhile WANG, Feng HU. Review on optical synthetic aperture imaging technique. Chinese Optics, 10, 25-38(2017).

[2] Zhixia SHEN, Lu FENG. -meter telescope, -30. https：//kepu.gmw.cn/astro/2019-03/11/content_32642506.htm

[3] D D S HALE, M BESTER, W C DANCHI et al. The Berkeley infrared spatial interferometer： a heterodyne stellar interferometer for the mid-infrared. Astrophysical Journal, 537, 998(2000).

[4] NAN Rendong, Peng JIANG. Five-hundred-meter aperture spherical radio telescope. Journal of Mechanical Engineering, 53, 1-3(2017).

[5] Xinji WU. The giant ear that listens to the cosmic waves-the development history of radio telescopes. China National Astronomy, 84-105(2008).

[6] Wanhong HAO, Haitao LI, Lei HUANG等. The very long baseline interferometry system of the deep space measurement and control network under construction. Journal of Spacecraft TT&C Technology, 31, 34-37(2012).

[7] Chunlai LI, Hongbo ZHANG, Xinying ZHU. Overview of VLBI technology in deep space exploration and its current situation and development in our country. Journal of Astronautics, 31, 1893-1899(2010).

[8] Yefei YUAN, Zeyuan TANG. First EHT images of the supermassive black hole residing in the center of nearby galaxy M87. Chinese Science Bulletin, 64, 2072-2076(2019).

[9] EVN and Global VLBI results and images. http：//old.evlbi.org/gallery/images.html

[10] Xiangping WU. Radio telescope： FAST&SKA. https：//www.sohu.com/a/233364715_313378

[11] The SKA project- public website. https：//www.skatelescope.org/ the-ska-project/

[12] Jianwei ZHOU, Daojing LI, Xuan HU. Target detection performance analysis of single illumination and triple observation passive radar. Journal of University of Chinese Academy of Sciences, 34, 422-430(2017).

[13] Jianwei ZHOU, Daojing LI, He TIAN等. Performance analysis on airship-borne passive radar based on conformal sparse array. Journal of Electronics and Information Technology, 39, 1058-1063(2017).

[14] B W KRAµSE, J BUCK, C RYAN et al. Synthetic aperture ladar flight demonstration(2011).

[15] S CROUCH, Z B BARBER. Laboratory demonstrations of interferometric and spotlight synthetic aperture ladar techniques. Optics Express, 20, 24237-24246(2012).

[16] Daojing LI, Qingjuan ZHANG, Bo LIU等. Key technology and implementation scheme analysis of air-borne synthetic aperture ladar. Journal of Radars, 2, 143-151(2013).

[17] MENG MA, Daojing LI, Jianbo DU. Imaging of airborne synthetic aperture ladar under platform vibration condition. Journal of Radars, 3, 591-602(2014).

[18] Jianbo DU, Daojing LI, Meng MA等. Vibration estimation and imaging of airborne synthetic aperture ladar based on interferometry processing. Chinese Journal of Lasers, 253-264(2016).

[19] Xuan HU, Daojing LI. Vibration phases estimation based on multi-channels interferometry for ISAL. Applied Optics, 57, 6481-6490(2018).

[20] Xuan HU, Daojing LI, Hanchu FU等. System analysis of ground-based inverse synthetic aperture lidar for geosynchronous orbit object imaging. Acta Photonica Sinica, 47, 0601003(2018).

[21] Xuan HU, Daojing LI, Jianbo DU. Imaging processing for GEO object with 3D rotation based on ground-based InISAL with orthogonal baselines. Applied Optics, 58, 3974-3985(2019).

[22] Z W BARBER, J R DAHL. Synthetic aperture ladar imaging demonstrations and information at very low return levels. Applied Optics, 53, 5531-5537(2014).

[23] Fei YIN. Canon developed the world's first 1-megapixel SPAD image sensor. https：//36kr.com/p/777895854557824

[24] Hai WANG. Design of a homodyne BPSK system for coherent optical communication(2009).

[25] Lu FENG, Yupei ZHANG, Feijun SONG等. Adaptive optics for night astronomy. Physics, 47, 355-366(2018).

[26] SPL Leica. new airborne lidar system officially released. https：//www.sohu.com/a/127882794_583961

[27] Chenfei JIN, Ye WANG, LU CAO等. Design of fiber-array imaging laser radar system. Opto-Electronic Engineering, 39, 115-123(2012).

[28] A YAACOBI, Jie SUN, M MORESCO et al. Integrated phased array for wide-angle beam steering. Optics Letters, 39, 4575-4578(2014).

[29] Jie SUN, T ERMAN et al. Large-scale nanophotonic phased array. Nature, 493, 195-199(2013).

[30] Meng MA, Daojing LI, Liechen LI等. 3-D imaging for moving targets based on millimeter-wave InISAR with long orthogonal baselines. Journal of Infrared and Millimeter, 35, 488-495(2016).

[31] Fei HE. Remote sensing of planetary space environment. Chinese Science Bulletin, 65, 1305-1309.

[32] Jianchao JIAO, Yun SU, Baohua WANG等. Development and application of GEO membrane based diffraction optical imaging system. Space International, 49-55(2016).

[33] Zhibin REN, Jiasheng HU, Honglang TANG等. Study on chromatic aberration correction of 10 meter large aperture membrane diffractive primary lens. Acta Photonica Sinica, 46, 0422004(2017).

[34] Hu ZHAN. The birth of "China Hubble" | Mr. Sai Astronomy. https：//mp.weixin.qq.com

[35] Xuan HU, Daojing LI. Space-based synthetic aperture LiDAR system with 10 m diffractive aperture. Chinese Journal of Lasers, 45, 1210002(2018).

[36] Daojing LI, Yu ZHU, Xuan HU等. Laser application and sparse imaging analysis of diffractive optical system. Journal of Radars, 9, 195-203(2020).

[37] Daojing LI, Xuan HU, Kai ZHOU等. Synthetic aperture lidar imaging detection based on conformal diffractive optical system. Acta Optica Sinica, 40, 0428001(2020).

[38] Jinyi ZHU, Yongjun XIE. Large aperture lidar receiver optical system based on diffractive primary lens. Infrared and Laser Engineering, 46, 0518001(2017).

[39] Yanchang DU, Tao LIU. The United States verifies the feasibility of the application of microlens interferometry optical imaging technology. https：//mp.weixin.qq.com

[40] Gang LI, Xuewu FAN, Gangyi ZOU等. Design of space optical system with double infrared waveband based on image space scanning. Infrared and Laser Engineering, 43, 861-866(2014).