[1] Zhao Z L, Huang J Y, Wu S D et al. Experimental demonstration of tri-aperture differential synthetic aperture ladar[J]. Optics Communications, 389, 181-188(2017).

[2] Mo D, Wang R, Wang N et al. Experiment of inverse synthetic aperture LADAR on real target[C]∥2017 7th IEEE International Conference on Electronics Information and Emergency Communication (ICEIEC), July 21-23, 2017, Macao, China., 319-321(2017).

[3] Zhao Z L, Wu J, Su Y Y et al. Three-dimensional imaging interferometric synthetic aperture ladar[J]. Chinese Optics Letters, 12, 091101(2014).

[4] Crouch S, Barber Z W. Laboratory demonstrations of interferometric and spotlight synthetic aperture ladar techniques[J]. Optics Express, 20, 24237-24246(2012).

[5] Beck S M, Buck J R, Buell W F et al. Synthetic-aperture imaging laser radar: laboratory demonstration and signal processing[J]. Applied Optics, 44, 7621-7629(2005).

[6] Guo L, Xing M D, Zhang L et al. Research on indoor experimentation of range SAL imaging system[J]. Science in China Series E: Technological Sciences, 52, 3098-3104(2009).

[7] Bashkansky M, Lucke R L, Funk E et al. Two-dimensional synthetic aperture imaging in the optical domain[J]. Optics Letters, 27, 1983-1985(2002).

[8] Wei F, Lu B, Wang J et al. Precision and broadband frequency swept laser source based on high-order modulation-sideband injection-locking[J]. Optics Express, 23, 4970-4980(2015).

[9] Wang N, Wang R, Mo D et al. Inverse synthetic aperture LADAR demonstration: system structure, imaging processing, and experiment result[J]. Applied Optics, 57, 230-236(2018).

[10] Li R M, Li W Z, Ding M L et al. Demonstration of a microwave photonic synthetic aperture radar based on photonic-assisted signal generation and stretch processing[J]. Optics Express, 25, 14334-14340(2017).

[11] Zhang F, Guo Q, Wang Z et al. Photonics-based broadband radar for high-resolution and real-time inverse synthetic aperture imaging[J]. Optics Express, 25, 16274-16281(2017).

[12] Krause B, Buck J, Ryan C et al. Synthetic aperture ladar flight demonstration. [C]∥CLEO: 2011-Laser Applications to Photonic Applications, May 1-6, 2011, Baltimore, Maryland. Washington, D.C.: OSA, PDPB7(2011).

[13] Huang Y X, Song S, Xu W M et al. Real-time inverse synthetic aperture ladar system based on continuous m-sequence phase modulation[J]. Laser & Optoelectronics Progress, 54, 072801(2017).

[14] Zhang J, Wang R, Zhang K S. Application and improvement of phase gradient autofocus algorithm in synthetic aperture lidar[J]. Laser & Optoelectronics Progress, 53, 062801(2016).

[15] Liu S J, Fu H C, Wei K et al. Jointly compensated imaging algorithm of inverse synthetic aperture lidar based on Nelder-Mead simplex method[J]. Acta Optica Sinica, 38, 0711002(2018).

[16] Yin H F, Guo L, Yang L C et al. Full aperture imaging algorithm of airborne synthetic aperture ladar[J]. Acta Optica Sinica, 39, 0928002(2019).

[17] Yakun L, Wu Y H, Wang H Y et al. Phase errors compensation algorithm of inverse synthetic aperture ladar based on CS-Fmea[C]∥2017 3rd IEEE International Conference on Computer and Communications (ICCC), December 13-16, 2017, Chengdu, China., 1313-1317(2017).

[18] Krause B, Gatt P, Embry C et al. High-resolution 3D coherent laser radar imaging[J]. Proceedings of SPIE, 6214, 277-287(2006).

[19] Chang S, Tong S F, Jiang H L et al. Optical phase-locked loop technology in inter-satellite high-speed coherent laser communication system[J]. Acta Optica Sinica, 37, 0206004(2017).

[20] Wu J, Zhao Z L, Wu S D et al. High resolution synthetic aperture ladar imaging at 12.9 m distance[J]. Acta Optica Sinica, 35, 1228002(2015).