References: [1] Weitkamp, Claus. (2005). Lidar: Range-Resolved Optical Remote Sensing of the Atmosphere, Springer Series in Optical Sciences, Springer Verlag, New York. [2] Tsamalis, C., Chedin, A., Pelon, J., Capelle, V. (2013). The Seasonal Vertical Distribution of the Saharan Air Layer and Its Modulation by the Wind, Atms. Chem. Phys., vol. 13, p. 11235-11257. [3] Chauvigne, A., Sellegri, K., Hervo, M., Montoux, N., Freville, P., Goloub, P. (2016). Comparison of the Aerosol Optical Properties and Size Distribution Retrieved by Sun Photometer with in Situ Measurements at Midlatitude, Atmos. Meas. Tech., vol. 9, p. 4569-4585. [4] Hey, V., Joshua, D. (2015). A Novel Lidar Ceilometer, Design, Implementation and Characterisation (Theory of Lidar), Springer, p. 23-41. [5] Masci, F. (1999). Algorithms for the Inversion of Lidar Signals: Rayleigh-Mie Measurements in the Stratosphere, Annali di Geofisika, 42 (1) 71-83, (February). [6] Stachlewska, I. S., Ritter, C. (2010). On Retrieval of Lidar Extinction Profiles Using Two-Stream and Raman Techniques, Atmos. Chem. Phys., 10 (6) 2813–2824. [7] Kovalev, V. A. (2015). Solutions in LIDAR Profiling of the Atmosphere, John Wiley & Sons, p. 1-77. [8] Mitsev, Ts. (2017). Lidar Inversion in the Case of Multilayer Aerosol Distribution, COMITE 2017, Burno, Czesh Republic, April 19- 21. [9] Klett, D. (1981). Stable Analytical Inversion Solution for Processing Lidar Returns, Appl. Opt., vol. 20, p. 211-220. [10] Klett, D. (1985). Lidar Inversion with Variable Backscatter/Extinction Ratios, Appl. Opt., vol. 24, p. 1638-1643. |