X. Chu, W. Pan, G. C. Papen, C. S. Gardner, J. A. Gelbwachs et al., Fe Boltzmann Temperature Lidar: Design, Error Analysis, and Initial Results at the North and South Poles, Earth Science and Applications from Space: National Imperatives for the Next Decade and Beyond, vol.41, pp.4400-4410, 2002.

E. C. Dawkins, A. Feofilov, L. Rezac, A. A. Kutepov, D. Janches et al., Validation of SABER v2.0 Operational Temperature Data With Ground-Based Lidars in the Mesosphere-Lower Thermosphere Region (75-105 km), J. Geophys. Res.-Atmos, vol.123, pp.9916-9934, 2018.

X. Dou, T. Li, J. Xu, H. Liu, X. Xue et al., Stability of temperatures from TIMED/SABER v1.07 (2002-2009) and Aura/MLS v2.2 (2004-2009) compared with OH(6-2) temperatures observed at Davis Station, García-Comas, vol.114, pp.11439-11446, 2009.

R. Wing, Lidar temperature series in the middle atmosphere as a reference data set -Part 2
URL : https://hal.archives-ouvertes.fr/insu-01960060

O. Mls and . Saber, Atmos. Meas. Tech, vol.7, pp.3633-3651, 2014.

A. Hauchecorne, L. Blanot, R. Wing, P. Keckhut, S. Khaykin et al., A new MesosphEO dataset of temperature profiles from 35 to 85 km using Rayleigh scattering at limb from GO-MOS/ENVISAT daytime observations, Atmos. Meas. Tech. Discuss, 2018.

K. W. Hoppel, N. L. Baker, L. Coy, S. D. Eckermann, J. P. Mccormack et al., Assimilation of stratospheric and mesospheric temperatures from MLS and SABER into a global NWP model, Atmos. Chem. Phys, vol.8, pp.6103-6116, 2008.
URL : https://hal.archives-ouvertes.fr/hal-00304147

K. W. Johnson and M. E. Gelman, Trends in upper stratospheric temperatures as observed by rocketsondes (1965-1983), International Council of Scientific Unions Handbook for MAP, International Council of Scientific Unions, vol.18, 1985.

T. Leblanc, I. S. Mcdermid, A. Hauchecorne, and P. Keckhut, Evaluation of optimization of lidar temperature analysis algorithms using simulated data, J. Geophys. Res.-Atmos, vol.103, pp.6177-6187, 1998.

T. Leblanc, R. J. Sica, J. A. Van-gijsel, S. Godin-beekmann, A. Haefele et al., Proposed standardized definitions for vertical resolution and uncertainty in the NDACC lidar ozone and temperature algorithmsPart 1: Vertical resolution, Atmos. Meas. Tech, vol.9, pp.4029-4049, 2016.

T. Leblanc, R. J. Sica, J. A. Van-gijsel, A. Haefele, G. Payen et al., Proposed standardized definitions for vertical resolution and uncertainty in the NDACC lidar ozone and temperature algorithms -Part 3: Temperature uncertainty budget, Licel: Licel Data Sheet Kernel Description, vol.9, pp.4079-4101, 2016.

N. J. Livesey, W. V. Snyder, W. G. Read, and P. A. Wagner, Retrieval algorithms for the EOS Microwave limb sounder (MLS), IEEE T. Geosci. Remote, vol.44, pp.1144-1155, 2006.

C. E. Meek, A. H. Manson, W. K. Hocking, and J. R. Drummond, Eureka, 80 ? N, SKiYMET meteor radar temperatures compared with Aura MLS values, Ann. Geophys, vol.31, pp.1267-1277, 2013.

C. J. Mertens, M. G. Mlynczak, M. López-puertas, P. P. Wintersteiner, R. H. Picard et al., Retrieval of mesospheric and lower thermospheric kinetic temperature from measurements of CO 2 15 µm Earth Limb Emission under non-LTE conditions, Geophys. Res. Lett, vol.28, pp.1391-1394, 2001.

P. Pautet, M. J. Taylor, W. R. Pendleton, Y. Zhao, T. Yuan et al., Advanced mesospheric temperature mapper for high-latitude airglow studies, Appl. Optics, vol.53, pp.5934-5943, 2014.

E. E. Remsberg, B. T. Marshall, M. Garcia-comas, D. Krueger, G. S. Lingenfelser et al., Assessment of the quality of the Version 1.07 temperature-versus-pressure profiles of the middle atmosphere from TIMED/SABER, J. Geophys. Res.-Atmos, vol.113, p.17101, 2008.

M. J. Schwartz, A. Lambert, G. L. Manney, W. G. Read, N. J. Livesey et al., Validation of the Aura Microwave Limb Sounder temperature and geopotential height measurements, J. Geophys. Res.-Atmos, vol.113, 2008.

V. Siva-kumar, P. B. Rao, M. Krishnaiah, V. Sivakumar, P. Vishnu-prasanth et al., Rayleigh LIDAR and satellite (HALOE, SABER, CHAMP and COSMIC) measurements of stratospheremesosphere temperature over a southern sub-tropical site, J. Geophys. Res.-Atmos, vol.108, pp.649-662, 2003.

A. Taori, N. Dashora, K. Raghunath, J. M. Russell, and M. G. Mlynczak, Simultaneous mesosphere-thermosphereionosphere parameter measurements over Gadanki (13.5 ? N, 79.2 ? E): First results, J. Geophys. Res.-Space, vol.116, 2011.

A. Taori, A. Jayaraman, K. Raghunath, and V. Kamalakar, A new method to derive middle atmospheric temperature profiles using a combination of Rayleigh lidar and O 2 airglow temperatures measurements, Ann. Geophys, vol.30, pp.27-32, 2012.

A. Taori, V. Kamalakar, K. Raghunath, S. Rao, J. Russell et al., Simultaneous Rayleigh lidar and airglow measurements of middle atmospheric waves over low latitudes in India, vol.44, pp.1075-1092, 2006.

R. Wing, A. Hauchecorne, P. Keckhut, S. Godin-beekmann, S. Khaykin et al., Lidar temperature series in the middle atmosphere as a reference data set -Part 1: Improved retrievals and a 20-year cross-validation of two co-located French lidars, The Climate Science Special Report (CSSR) of the Fourth National Climate Assessment (NCA4), in: AGU Fall Meeting Abstracts, vol.11, pp.5531-5547, 2016.
URL : https://hal.archives-ouvertes.fr/insu-01893038

J. Xu, C. Y. She, W. Yuan, C. Mertens, M. Mlynczak et al., Comparison between the temperature measurements by TIMED/SABER and lidar in the midlatitude, J. Geophys. Res.-Space, vol.111, 2006.

T. Yuan, C. She, D. Krueger, S. C. Reising, X. Zhang et al., A collaborative study on temperature diurnal tide in the midlatitude mesopause region (41 ? N, 105 ? W) with Na lidar and TIMED/SABER observations, J. Atmos. Sol.-Terr, vol.72, pp.541-549, 2010.

C. Yue, G. Yang, J. Wang, S. Guan, L. Du et al., Lidar observations of the middle atmospheric thermal structure over north China and comparisons with TIMED/SABER, J. Atmos. Sol.-Terr, vol.120, pp.80-87, 2014.