[1] Liu Z S, Liu B Y, Wu S H et al. High spatial and temporal resolution mobile incoherent Doppler lidar for sea surface wind measurements[J]. Optics Letters, 33, 1485-1487(2008).

[2] Song X Q, Long W R, Yun L et al. Analysis of accuracy and acquisition rate of Doppler lidar multi-beam wind measurement[J]. Acta Optica Sinica, 41, 1001001(2021).

[3] Wang X Y, Wu S H, Liu X Y et al. Observation of aircraft wake vortex based on coherent Doppler lidar[J]. Acta Optica Sinica, 41, 0901001(2021).

[4] Yuan L C, Liu H, Liu J Q et al. Wind vector estimation of coherent Doppler wind lidar based on genetic algorithm[J]. Chinese Journal of Lasers, 47, 0810004(2020).

[5] Shen F H, Zhuang P, Wang B X et al. Research on retrieval method of low-altitude wind field for Rayleigh-Mie scattering Doppler lidar[J]. Chinese Journal of Lasers, 48, 1110005(2021).

[6] Liu B Y, Liu Z S, Song X Q et al. Modifications and moving measurements of mobile Doppler lidar[J]. Proceedings of Dragon 2 Programme Mid-Term Results 2008-2010, May 17-21, 2010, Guilin, China(2010).

[7] Bilbro J, Fichtl G, Fitzjarrald D et al. Airborne Doppler lidar wind field measurements[J]. Bulletin of the American Meteorological Society, 65, 348-359(1984).

[8] Chen B L, Yang Z D, Min M et al. Application requirements and research progress of spaceborne Doppler wind lidar[J]. Laser & Optoelectronics Progress, 57, 190003(2020).

[9] Zhai X C, Wu S H, Liu B Y et al. Shipborne wind measurement and motion-induced error correction of a coherent Doppler lidar over the Yellow Sea in 2014[J]. Atmospheric Measurement Techniques, 11, 1313-1331(2018).

[10] Gottschall J, Gribben B, Stein D et al. Floating lidar as an advanced offshore wind speed measurement technique: current technology status and gap analysis in regard to full maturity[J]. Wiley Interdisciplinary Reviews: Energy and Environment, 6, e250(2017).

[11] Tiana-Alsina J, Gutiérrez M A, Würth I et al. Motion compensation study for a floating Doppler wind LiDAR[C], 5379-5382(2015).

[12] Kelberlau F, Neshaug V, Lønseth L et al. Taking the motion out of floating lidar: turbulence intensity estimates with a continuous-wave wind lidar[J]. Remote Sensing, 12, 898(2020).

[13] Carbon Trust Offshore Wind Accelerator (OWA). Carbon trust offshore wind accelerator roadmap for the commercial acceptance of floating lidar technology[EB/OL]. https://www.carbontrust.com/resources/roadmap-for-commercial-acce ptance-of-floating-lidar

[14] Gottschall J, Wolken-Möhlmann G, Viergutz T et al. Results and conclusions of a floating-lidar offshore test[J]. Energy Procedia, 53, 156-161(2014).

[15] Hsuan C Y, Tasi Y S, Ke J H et al. Validation and measurements of floating LiDAR for nearshore wind resource assessment application[J]. Energy Procedia, 61, 1699-1702(2014).

[16] Gutiérrez-Antuñano M A, Tiana-Alsina J, Rocadenbosch F et al. A wind-lidar buoy for offshore wind measurements: first commissioning test-phase results[C], 1607-1610(2017).

[17] Huang X X, Tao Y J, Guan M K. Research on the development of floating lidar wind measurement for offshore wind power[J]. China Water Transport, 19, 57-58(2019).

[18] Browning K A, Wexler R. The determination of kinematic properties of a wind field using Doppler radar[J]. Journal of Applied Meteorology, 7, 105-113(1968).

[19] Wang G N, Liu B Y, Feng C Z et al. Data quality control method for VAD wind field retrieval based on coherent wind lidar[J]. Infrared and Laser Engineering, 47, 0230002(2018).

[20] Zeng S E. The vector mean method of wind[J]. Meteorological Monthly, 9, 21-22(1983).