[1] MOLEBNY V, MCMANAMON P, STEINVALL O et al. Laser radar： historical prospective-from the east to the west[J]. Optical Engineering, 56(2017).

[2] ARIKUMAR K S, DEEPAK KUMAR A, GADEKALLU T R et al. Real-time 3D object detection and classification in autonomous driving environment using 3D LiDAR and camera sensors[J]. Electronics, 11, 4203(2022).

[3] ALDAO E, GONZÁLEZ-DE SANTOS L, GONZÁLEZ-JORGE H. LiDAR based detect and avoid system for UAV navigation in UAM corridors[J]. Drones, 6, 185(2022).

[4] PANEQUE J, VALSECA V, MARTINEZ-DE DIOS J R et al. Autonomous reactive LiDAR-based mapping for powerline inspection[C], 21, 962-971(2022).

[5] LOPAC N, JURDANA I, BRNELIĆ A et al. Application of laser systems for detection and ranging in the modern road transportation and maritime sector[J]. Sensors, 22, 5946(2022).

[6] NOROUZIAN F, PIRKANI A, HOARE E et al. Phenomenology of automotive radar interference[J]. IET Radar, 15, 1045-1060(2021).

[7] WANG Y, ZHANG Q, WEI Z et al. Performance analysis of uncoordinated interference mitigation for automotive radar[J]. IEEE Transactions on Vehicular Technology, 72, 4222-4235(2023).

[8] HAIDER A, PIGNICZKI M, KÖHLER M H et al. Development of high-fidelity automotive LiDAR sensor model with standardized interfaces[J]. Sensors, 22, 7556(2022).

[9] KIM G, PARK Y. Alien pulse rejection in concurrent firing LIDAR[J]. Remote Sensing, 14, 1129(2022).

[10] MATTHEY R, MITEV V. Pseudo-random noise-continuous-wave laser radar for surface and cloud measurements[J]. Optics and Lasers in Engineering, 43, 557-571(2005).

[11] YANG Z J, LI C, YU M et al. Compact 405-nm random-modulation continuous wave lidar for standoff biological warfare detection[J]. Journal of Applied Remote Sensing, 9(2015).

[12] QUATREVALET M, AI X, PEREZ-SERRANO A et al. Atmospheric CO₂ sensing with a random modulation continuous wave integrated path differential absorption lidar[J]. IEEE Journal of Selected Topics in Quantum Electronics, 23, 157-167(2017).

[13] XU Z Y, YU F X, QIU B W et al. Coherent random-modulated continuous-wave LiDAR based on phase-coded subcarrier modulation[J]. Photonics, 8, 475(2021).

[14] AI X, NOCK R, RARITY J G et al. High-resolution random-modulation cw lidar[J]. Applied Optics, 50, 4478-4488(2011).

[15] HWANG I P, LEE C H. Mutual interferences of a true-random LiDAR with other LiDAR signals[J]. IEEE Access, 8, 124123-124133(2020).

[16] SCIAMANNA M, SHORE K A. Physics and applications of laser diode chaos[J]. Nature Photonics, 9, 151-162(2015).

[17] WANG A B, YANG Y B, WANG B J et al. Generation of wideband chaos with suppressed time-delay signature by delayed self-interference[J]. Optics Express, 21, 8701-8710(2013).

[18] ZHANG T SH, WANG B J, XU H et al. Mutual interference suppression of chaotic imaging lidar for automotive application[J]. Semiconductor Optoelectronics, 42, 424-429(2021).

     张天舒, 王冰洁, 徐航. 面向车载应用的混沌激光成像雷达抑制交叉干扰实验研究[J]. 半导体光电, 42, 424-429(2021).

[19] CHEN J-D, WU K-W, HO H L et al. 3-D multi-input multi-output （MIMO） pulsed chaos lidar based on time-division multiplexing[J]. IEEE Journal of Selected Topics in Quantum Electronics, 28, 1-9(2022).

[20] LUKASHCHUK A, RIEMENSBERGER J, STROGANOV A et al. Chaotic microcomb inertia-free parallel ranging[J]. APL Photonics, 8(2023).