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Vol. 32, issue 11, article # 9

Karavaev D. M., Shchukin G. G. Study on variations in water vapor and cloud liquid using microwave radiometry. // Optika Atmosfery i Okeana. 2019. V. 32. No. 11. P. 930–935. DOI: 10.15372/AOO20191109 [in Russian].
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Abstract:

In article the possibilities of modern microwave radiometers to the study of variations of characteristics of atmospheric moisture are discusses. Based on analysis of ground-based, ship and satellite microwave radiometers investigated variations of atmospheric water vapor and cloud liquid in a wide range of time scales in different regions over the ocean and over land, to describe the approximation obtained temporary structural function of water vapor.

Keywords:

water vapor, cloud liquid, microwave radiometer, temporal structure functions

References:

  1. Stepanenko V.D., Shchukin G.G, Bobylev L.P., Matrosov S.Yu. Radioteplolokatsiya v meteorologii. L.: Gidrometeoizdat, 1987. 283 p.
  2. Basharinov A.E., Gurvich A.S., Egorov S.T. Radioizluchenie zemli kak planety. M.: Nauka, 1974. 118 p.
  3. Ware R., Carpenter R., Güldner J., Liljegren J., Nehrkorn T., Solheim F., Vandenberghe F. A multichannel radiometric profiler of temperature, humidity, and cloud liquid // Radio Science. 2003. V. 38, N 4. P. 8079–8092.
  4. Kadygrov E.N., Gorelik A.G., Miller E.A., Nekrasov V.V., Troitskij A.V., Tochilkina T.A., Shaposhnikov A.N. Rezul'taty monitoringa termodinamicheskogo sostoyaniya troposfery mnogokanal'nym mikrovolnovym radiometricheskim kompleksom // Optika atmosf. i okeana. 2013. V. 26, N 6. P. 459–465.
  5. Il'in G.N., Bykov V.Yu., Stempkovskij V.G. Sistema monitoringa troposfernyh parametrov na osnove radiometra vodyanogo para // Tr. IPA RANtermodinamicheskogo sostoyaniya troposfery mnogokanal'nym mikrovolnovym radiometricheskim kompleksom // Optika atmosf. i okeana. 2013. Iss. 27. P. 204–201.
  6. Kutuza B.G. Spatial and temporal fluctuations of atmospheric microwave emission // Radio Sci. 2003. V. 38, N 3. P. 8047–8059.
  7. Kutuza B.G., Egorov D.P., Kazaryan R.A. Vliyanie vodyanogo para i oblachnosti na fluktuatsii radioizlucheniya atmosfery v chastotnom diapazone 18–27 GHz // XI Vseros. konf. «Radiolokatsiya i svyaz'». M., 2016. P. 203–206.
  8. Karavaev D.M., Shchukin G.G. Sostoyanie i perspektivy primeneniya mikrovolnovoj radiometrii atmosfery // Optika atmosf. i okeana. 2015. V. 28, N 12. P. 1122–1127; Kаrаvаеv D.М., Shchukin G.G. Status and prospects of application of microwave radiometry of the atmosphere // Atmos. Ocean. Opt. 2016. V. 29,  N 3. P. 308–314.
  9. Cimini D., Westwater Ed.R., Gasiewski A.W., Klein M., Leuski V.Y., Liljegren J.S. Ground-based millimeter- and submillimeter-wave observations of low vapor and liquid water contents // IEEE Trans. Geosci. Remote Sens. 2007. V. 45, N 7. P. 2169–2180.
  10. Gorelik A.G., Dombkovskaya E.P., Ozerkina V.V., Semiletov V.I., Skuratova I.S., Frolov A.V. Mikrovolnovye polyarizatsionnye izmereniya na sputnike «Meteor» // Meteorol. i gidrol. 1975. N 7. P. 36–45.
  11. Jackson T.J., Hsu A.Y., Shutko A., Tishenko Y., Petrenko B., Kutuza B., Armand N. Priroda microwave radiometer observations in the Southern Great Plains 1997 hydrology experiment // Int. J. Remote Sens. 2002. V. 23, N 2. P. 231–248.
  12. Kutuza B.G., Danilychev M.V., Yakovlev O.I. Sputnikovyj monitoring Zemli. Mikrovolnovaya radiometriya atmosfery i poverhnosti. M.: Lenand, 2016. P. 336.
  13. Boldyrev V.V., Gorobets N.N., Il'gasov P.A., Nikitin O.V., Pantsov V.Yu., Prohorov YU.N., Strel'nikov N.I., Strel'tsov A.M., Chernyj I.V., Chernyavskij G.M., Yakovlev V.V. Sputnikovyj mikrovolnovyj skaner/zondirovshchik MTVZA-GYA // Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa. 2008. V. 1, iss. 5. P. 243–248.
  14. Tatarskij V.I. Rasprostranenie voln v turbulentnoj atmosfere. M.: Nauka, 1967. 548 p.
  15. Stotskii A.A. Path length fluctuations through the Earth troposphere: Turbulent model and data of observations // Proc. Sympos. Refractions of Transatmospheric Signals in Geodesy. The Netherlands, 1992. P. 179–182.
  16. Marchuk G.I. Proekt nauchnoj programmy po issledovaniyu roli energoaktivnyh zon okeana v kolebaniyah klimata. M.: Gidrometeoizdat, 1989. 109 p.
  17. Efremenko A.N., Karavaev D.M., Shchukin G.G. O vozmozhnosti postroeniya poluempiricheskoj modeli variatsij vlagozapasa atmosfery po dannym mikrovolnovoj radiometrii // IX Armandovskie chteniya: Vseros. nauch. konf. «Sovremennye problemy distantsionnogo zondirovaniya, radiolokatsii, rasprostraneniya i difraktsii voln». Murom, 28–30 may 2019 year IPTS MI VlGU, 2019. P. 291–294. URL: www.mivlgu.ru/conf/armand/armandovskie-chteniya-archive (last access: 17.04.2019).
  18. Karavaev D.M., Shchukin G.G. Issledovanie variatsij harakteristik mikrovolnovogo izlucheniya i parametrov vlagosoderzhaniya atmosfery // Materialy VII Vseros. nauch. konf. VI Armandovskie chteniya. Radiofizicheskie metody v distantsionnom zondirovanii sred. Murom: IPTS MI VlGU, 2016. P. 73–76.
  19. Wentz F.J. A well-calibrated ocean algorithm for special sensor microwave/imager // J. Geophys. Research. 1997. V. 102, N C4. P. 8703–8718.
  20. Karavaev D.M., Shchukin G.G. Issledovanie variatsij vlagozapasa atmosfery i vodozapasa oblakov po dannym mikrovolnovyh radiometrov // Materialy 30 Vseros. simpoz. «Radiolokatsionnoe issledovanie prirodnyh sred». SPb.: VKA im. A.F. Mozhajskogo, 2017. V. 2, iss. 12. P. 204–214.
  21. Vasishcheva M.A., Shchukin G.G. Eksperimental'nye issledovaniya vodnosti oblakov. Statisticheskie modeli atmosfery. Obninsk: VNIIGMI-MTSD, 1977. 94 p.