[1] D R Lv, Z Y Chen, X Guo, et al. Recent progress in near space atmospheric environment study. Advances in Mechanics, 39, 674-682(2009).
[2] C Y Xiao, X Hu, B Wang, et al. Quantitative studies on the variations of near space atmospheric fluctuation. Chinese Journal of Geophysics, 59, 1211-1221(2016).
[3] J X Shi, X Q Song, S H Wu, et al. Doppler lidar telemetry for wind turbine vibration. Optics and Precision Engineering, 28, 2180-2191(2020).
[4] C Y She, H Latifi, J R Yu, et al. Two-frequency Lidar technique for mesospheric Na temperature measurements. Geophysical Research Letters, 17, 929-932(1990).
[5] Bills R E. Iron Sodium Dopplertemperature lidar studies of the upper mesosphere[D]. Urbana: University of Illinois at UrbanaChampaign, 1991.
[6] C Y She, J R Yu. Simultaneous three-frequency Na lidar measurements of radial wind and temperature in the mesopause region. Geophysical Research Letters, 21, 1771-1774(1994).
[7] White M A. A frequencyagile Na lidar f the measurement of temperature velocity in the mesopauseregion[D]. Ft Collins: Colado State University, 1999.
[8] C Y She, J Sherman, T Yuan, et al. The first 80-hour continuous lidar campaign for simultaneous observation of mesopause region temperature and wind. Geophysical Research Letters, 30, 1319-1323(2003).
[9] Acott P E. Mesosphere momentum flux studies over Ft Collins CO(41N, 105W)[D]. Ft Collins: Colado State University, 2009.
[10] X Hu, Z A Yan, S Y Guo, et al. Sodium fluorescence Doppler lidar to measure atmospheric temperature in the mesopause region. Chinese Science Bulletin, 56, 417-423(2011).
[11] J Ba, X Hu, Z A Yan, et al. Observation analysis on the characteristics of vertical dynamical transport of sodium atoms in the mesopause region over the Langfang area. Chinese Journal of Geophysics, 61, 449-457(2018).
[12] T Li, X Fang, W Liu, et al. A narrowband sodium lidar for the measurements of mesopause region temperature and wind. Applied Optics, 51, 5401-5411(2012).
[13] D R Lu, W L Pan, Y N Wang. Atmospheric profiling synthetic observation system in Tibet. Advances in Atmospheric Sciences, 35, 264-267(2018).
[14] C A Tepley. The Doppler Rayleigh lidar system at arecibo. IEEE Transactions on Geoscience and Remote Sensing, 30, 36-47(1993).
[15] J S Friedman, C A Tepley, P A Castlebery, et al. Middle-atmospheric Doppler lidar using an iodine-vapor edge filter. Optics Letters, 22, 1648-1650(1997).
[16] C Souprayen, A Garnier, A Hertzog, et al. Reyleigh-Mie Doppler wind lidar for atmospheric measurements. I. Instrumental setup, validation, and first climatological results. Applied Optics, 38, 2410-2421(1999).
[17] G Baumgarten. Doppler Rayleigh/Mie/Raman Lidar for wind and temperature measurements in the middle atmosphere up to 80 km. Atmospheric Measurement Techniques, 3, 1509-1518(2010).
[18] G Baumgarten, J Fiedler, J Hildebrand, et al. Inertia gravity wave in the stratosphere and mesosphere observed by Doppler Wind and temperature lidar. Geophysical Research Letters, 42, 10929-10936(2015).
[19] X Dou, Y Han, D Sun, et al. Mobile Rayleigh Doppler lidar for wind and temperature measurements in the stratosphere and lower mesosphere. Optics Express, 22, A1203-A1221(2014).
[20] R C Zhao, X K Dou, D S Sun, et al. Gravity waves observation of wind field in stratosphere based on a Rayleigh Doppler lidar. Optics Express, 24, A581-A591(2016).
[21] F Han, H J Liu, D S Sun, et al. Design and analysis of ultra-narrow filter of Rayleigh lidar. Infrared and Laser Engineering, 49, 0205003(2020).
[22] Y Z Wang, Y L Han, D S Sun, et al. Multi-season observation and analysis of quasi-zero wind layer based on Doppler lidar in middle latitudes of China. Infrared and Laser Engineering, 49, 0305004(2020).
[23] Z A Yan, X Hu, W J Guo et al. Development of a mobile Doppler lidar system for wind and temperature measurements at 30-70 km. Jouranal of Quantitative Spectroscopy & Radiative Transfer, 188, 52-59(2017).
[24] C Y She, J Yue, Z A Yan, et al. Direct-detection Doppler wind measurements with a Cabannes-Mie lidar: A comparison between iodine vapor filter and Fabry-Perot interferometer methods. Appled Optics, 46, 4434-4443(2007).
[25] C S Gardner. Performance capabilities of middle-atmosphere temperature lidars: comparison of Na, Fe, K, Ca, Ca+, and Rayleigh systems. Applied Optics, 43, 4941-4956(2004).
[26] Z A Yan, X Hu, S Y Guo. Sodium atoms D2 line Doppler-free saturation fluorescence spectra measurements. Acta Optica Sinica, 30, 1036-1040(2010).
[27] J Ba, Z A Yan, X Hu, et al. Characteristics of vertical wind perturbations in the mesopauseregion based on lidar measurements and dynamic simulations. Chinese Journal of Space Science, 37, 554-563(2017).
[28] J Ba, X Hu, Z A Yan et al. Lidar observations of atmospheric gravity wave dissipation included Na atoms transportations in the mesopause region at Langfang, China. Chinese Journal of Geophysics, 60, 499-506(2017).
[29] W J Guo, Z A Yan, X Hu, et al. Measuring the three-dimensional structure of gravity waves by Lidar. Chinese Journal of Geophysics, 63, 394-400(2020).
[30] H X Tong, C Z Tong, Z Y Wang, et al. Advances in the technology of 850 nm high-speed vertical cavity surface emitting lasers. Infrared and Laser Engineering, 49, 20201077(2020).
[31] Q Liu, C Liu, X L Zhu, et al. Analysis of the optimal operating wavelength of spaceborne oceanic lidar. Chinese Optics, 13, 148-155(2020).
[32] W W He, K J Wu, D Fu, et al. Instrument design and forward modeling of near-space wind and temperature sensing interferometer. Optics and Precision Engineering, 28, 1678-1689(2020).
[33] Tong Y C, Tong X D, Zhang K, et al. Polarizationlidar gain ratio calibration method: a comparison[J]. Chinese Optics, In press.(in Chinese) doi: 10.37188CO.20200136.