[1] Zhao H, Hua D X, Di H G et al. Development of all time multi-wavelength lidar system and analysis of its signal to noise ratio[J]. Chinese Journal of Lasers, 42, 0113001(2015).

[2] Dai Y J[M]. Laser and infrared sounds principle, 271-272(2012).

[3] Althausen D, Müller D, Ansmann A et al. Scanning 6-wavelength 11-channel aerosol lidar[J]. Journal of Atmospheric and Oceanic Technology, 17, 1469-1482(2000).

[4] Wang Y F, Hua D X, Wang H W et al. Analysis of all-fiber Raman lidar system for water vapor by fiber Fabry-Perot filters[J]. Chinese Journal of Quantum Electronics, 30, 103-109(2013).

[5] Xu L M. Development of a compact Mie lidar system for atmospheric aerosol detection Xi'an: Xi'an University of[D]. Technology, 1-5(2008).

[6] Mao J T, Zhang J H, Wang M H. Summary comment on research of atmospheric aerosl in China[J]. Acta Meteorologica Sinica, 60, 625-634(2002).

[7] Qiu J H, Chen H B[M]. Atmospheric physics and atmospheric sounding, 11-12(2005).

[8] Luo H H, Chen Z Y, Zhang T S et al. Comparison of aerosol vertical distribution based on CALIPSO satellite and ground observation data[J]. Chinese Journal of Lasers, 46, 1201003(2019).

[9] Qiu J H, Lü D R, Chen H B et al. Modern research progresses in atmospheric physics[J]. Chinese Journal of Atmospheric Sciences, 27, 628-652(2003).

[10] Müller D, Wandinger U, Ansmann A. Microphysical particle parameters from extinction and backscatter lidar data by inversion with regularization: theory[J]. Applied Optics, 38, 2346-2357(1999).

[11] Müller D, Wandinger U, Ansmann A. Microphysical particle parameters from extinction and backscatter lidar data by inversion with regularization: simulation[J]. Applied Optics, 38, 2358-2368(1999).

[12] Müller D, Wagner F, Wandinger U et al. Microphysical particle parameters from extinction and backscatter lidar data by inversion with regularization: experiment[J]. Applied Optics, 39, 1879-1892(2000).

[13] Wang X C, Rao R Z. Lidarratios for atmospheric aerosol and cloud particles[J]. Chinese Journal of Lasers, 32, 1321-1324(2005).

[14] Chi R L, Wu D C, Liu B et al. Dual-wavelength Mie lidar for measuring the whole tropospheric aerosols[J]. Journal of Atmospheric and Environmental Optics, 3, 179-186(2008).

[15] Chi R L, Wu D C, Liu B et al. Dual-wavelength Mie lidar observations of tropospheric aerosols[J]. Spectroscopy and Spectral Analysis, 29, 1468-1472(2009).

[16] Bo G Y, Liu D, Wang B X et al. Two-wavelength polarization airborne lidar for observation of aerosol and cloud[J]. Chinese Journal of Lasers, 39, 1014002(2012).

[17] Zhou J, Yue G M, Jin C J et al. Two-wavelength Mie lidar for monitoring of tropospheric aerosol[J]. Acta Optica Sinica, 20, 1412-1417(2000).

[18] Di H G, Hua D X, Wang Y F et al. Investigation on the correction of the Mie scattering lidar's overlapping factor and echo signals over the total detection range?[J]. Acta Physica Sinica, 62, 242-248(2013).

[19] Cheng X W, Song J, Li F Q et al. Dual-wavelength high altitude detecting lidar technology[J]. Chinese Journal of Lasers, 33, 601-606(2006).

[20] Zhong Z Q, Liu B, Fan A Y et al. Two-wavelength Mie lidar with two receivers[J]. Journal of Atmospheric and Environmental Optics, 3, 173-178(2008).

[21] Di H G, Hou X L, Zhao H et al. Detections and analyses of aerosol optical properties under different weather conditions using multi-wavelength Mie lidar[J]. Acta Physica Sinica, 63, 244206(2014).

[22] Schotland R M. Errors in the lidar measurement of atmospheric gases by differential absorption[J]. Journal of Applied Meteorology, 13, 71-77(1974).

[23] Liu D, Wang Y J, Tao Z M et al. Development of three-wavelength-Raman-polarization lidar system and case study[J]. Acta Optica Sinica, 33, 0228001(2013).

[24] Bo G Y, Liu D, Wu D C et al. Two-wavelength lidar for observation of aerosol optical and hygroscopic properties in fog and haze days[J]. Chinese Journal of Lasers, 41, 0113001(2014).