[1] Hong G L, Li J T, Kong W et al. 935 nm differential absorption lidar system and water vapor profiles in convective boundary layer[J]. Acta Optica Sinica, 37, 0201003(2017).

[2] Wang Y F, Gao F, Zhu C X et al. Raman lidar for atmospheric temperature, humidity and aerosols up to troposphere height[J]. Acta Optica Sinica, 35, 0328004(2015).

[3] Shibata T, Kobuchi M, Maeda M. Measurements of density and temperature profiles in the middle atmosphere with a XeF lidar[J]. Applied Optics, 25, 685-687(1986).

[4] Hauchecorne A, Chanin M L. Density and temperature profiles obtained by lidar between 35 and 70 km[J]. Geophysical Research Letters, 7, 565-568(1980).

[5] Shimizu H, Lee S A, She C Y. High spectral resolution lidar system with atomic blocking filters for measuring atmospheric parameters[J]. Applied Optics, 22, 1373-1381(1983).

[6] She C Y, Alvarez R J, Caldwell L M et al. High-spectral-resolution Rayleigh-Mie lidar measurement of aerosol and atmospheric profiles[J]. Optics Letters, 17, 541-543(1992).

[7] Korb C L, Weng C Y. Differential absorption lidar technique for measurement of the atmospheric pressure profile[J]. Applied Optics, 22, 3759-3770(1983).

[8] Schwemmer G K, Dombrowski M, Korb C L et al. A lidar system for measuring atmospheric pressure and temperature profiles[J]. Review of Scientific Instruments, 58, 2226-2237(1987).

[9] Korb C L, Schwemmer G K, Dombrowski M et al. Airborne and ground based lidar measurements of the atmospheric pressure profile[J]. Applied Optics, 28, 3015-3020(1989).

[10] Flamant C N, Schwemmer G K, Korb C L et al. Pressure measurements using an airborne differential absorption lidar. Part I: analysis of the systematic error sources[J]. Journal of Atmospheric and Oceanic Technology, 16, 561-574(1999).

[11] Stephen M, Krainak M, Riris H et al. Narrowband, tunable, frequency-doubled, erbium-doped fiber-amplifed transmitter[J]. Optics Letters, 32, 2073-2075(2007).

[12] Stephen M A, Mao J P, Abshire J B et al. Oxygen spectroscopy laser sounding instrument for remote sensing of atmospheric pressure. [C]∥Digital Holography and Three-Dimensional Imaging, March 17-19, 2008, St. Petersburg, Florida, United States. Washington, D.C.: OSA, JMA19(2008).

[13] Riris H, Rodriguez M D, Allan G R et al. Airborne lidar measurements of atmospheric pressure made using the oxygen A-band. [C]∥Lasers, Sources, and Related Photonic Devices, January 29-February 1, 2012, San Diego, California, United States. Washington, D.C.: OSA, LT2B, 5(2012).

[14] Riris H, Rodriguez M, Allan G R et al. Pulsed airborne lidar measurements of atmospheric optical depth using the Oxygen A-band at 765 nm[J]. Applied Optics, 52, 6369-6382(2013).

[15] Hong G L, Wang Q, Kong W et al. Operating wavelength selection for spaceborne differential absorption lidar measuring surface pressure[J]. Journal of Infrared and Millimeter Waves, 37, 206-211(2018).

[16] Wang Q. Research on 760 nm Lidar for Atmospheric Pressure Measurement[D]. Beijing: University of Chinese Academy of Sciences(2019).

[17] Hong G L, Wang Q, Xiao C L et al. A laser transmitter of differential absorption lidar for atmospheric pressure measurement[J]. Journal of Infrared and Millimeter Waves, 38, 451-458(2019).

[18] He Y, Baxter G W, Orr B J. Locking the cavity of a pulsed periodically poled lithium niobate optical parametric oscillator to the wavelength of a continuous-wave injection seeder by an “intensity-dip” method[J]. Review of Scientific Instruments, 70, 3203-3213(1999).