Vol. 2, issue 11, article # 3

pdf Dzhetybaev E. O., Muldashev T. Z., Mishin I. V. Calculation of optical transfer functions of the atmosphere. // Atmospheric and oceanic optics. 1989. V. 2. No. 11. P. 1135-1140.
Copy the reference to clipboard

Numerical data on the atmospheric optical transfer functions, obtained by the spherical harmonics, Monte-Carlo, source function, and iteration methods are compared. The calculations were carried out using atmospheric models.


1. G.I.  Marchuk, G.A. Mikhailov, and M.A. Nazaraliev, The Monte-Carlo Method in Atmospheric Optics (Nauka, Novosibirsk, 1976).
2. J. Lenoble [Ed.], Standard Procedure for Computing Atmospheric Radiative Transfer in a Scattering Atmosphere, Boulder, Colorado: NCAR, Vol. 1, 124 (1979).
3. Yu.L. Biryukov and Yu.V. Krylov, Izv. Akad. Nauk, FAO, 10, No. 11, 1231 (1974).
4. A.H. Karp, JQSRT 25, No. 5, 403 (1981).
5. M.V. Maslenikov and T.A. Sushkevich [Eds.], Numerical Solution of Problems on Atmospheric Optics, M.V. Keldysh Institute of Applied Mechanics, Moscow (1984).
6. G.M. Krekov, V.M. Orlov, V.V. Belov, et al., Simulational Modeling in Problems of Optical Remote Sensing (Nauka, Novosibirsk, 1988).
7. M.A. Nazaraliev, Numerical Modeling of Radiative Fields in the Atmosphere by the Monte-Carlo Method, Author’s Abstract of Doct. Phys.-Math. Sci. Dissert., Computing Center of the Siberian Branch of the Academy of Sciences of the USSR, Novosibirsk (1985).
8. E.O. Dzhetybaev, I.V. Mishin, T.Z. Muldashev, et al., Calculations of Optical Transmission Characteristics of the Atmosphere, Preprint No. 1475, IKI Acad. Sci. USSR, 55, Moscow (1989).
9. A.A. Ioltukhovskii, S.A. Strelkov, and T.A. Sushkevich, Test Models for Computational Solution of the Transfer Equation, Preprint, No. 150, M.V. Keldysh Inst. of Appl. Math. of Acad. Sci. USSR, 25, Moscow (1988).
10. L. Elterman, UV, Visible, and IR Attenuation for Altitudes to 50 km, Report AFCRL-68-0153- Environ. Res. Papers, No. 285, 60 (1968).
11. G.M. Krekov and R.F. Rakhimov, Optical-Locational Model for Continental Aerosol (Nauka, Novosibirsk, 1982).
12. T.Z. Muldashev and U.M. Sultangazin, Zh. Vych. Mekh. Math. Fiz. 26, No. 6, 882.
13. T.Z. Muldashev, Method of Spherical Harmonics for Calculation of the Optical Spatial-frequency Characteristic of the Atmosphere, VINITI, No. 1879-B87, Moscow (1987).
14. B.A. Kargin, Satellite-Based Methods for Investigating the Natural Environment of Siberia and the Far East (Nauka, Novosibirsk, 1983).
15. V.G. Zolotukhin, I.V. Mishin, and D.A. Usikov, Issled. Zemli iz Kosmosa. No. 4, 14 (1984).
16. I.V. Mishin and A.P. Tishchenko, Issled. Zemli iz Kosmosa. No. 1, 48 (1981).
17. E.O. Dzhetybaev, Statistical Modeling Algorithms in the Problem of Remote Optical Sensing of the System ”Atmosphere-Ocean", Author’s Abstract of Cand. Phys.-Math. Sci. Dissert., Computing Center of the Siberian Branch of the Academy of Sciences of the USSR, Novosibirsk (1983).