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Radar monitoring of long surface waves in the pacific ocean

Рубрика: 
RADIOWAVE PROPAGATION, RADIOLOCATION AND REMOTE SENSING
Velichko, SA, Matveev, АY, Bychkov, DM, Ivanov, VK, Tsymbal, VN, Gavrilenko, OS
Organization: 

O.Ya. Usikov Institute for Radiophysics and Electronics of the NASU
12, Acad. Proskura St., Kharkov, 61085, Ukraine
E-mail: ayamatweev2017@gmail.com
https://doi.org/10.15407/rej2021.01.003
Язык: ukranian
Аннотация: 

Subject and Purpose. The paper addresses interaction processes going in the oceanatmosphere system and is concerned with their research by the method of radar remote sensing. Specifically, the matter of concern is the detection and parameter estimation of long waves, including nonlinear ones, on the ocean surface.

Methods and Methodology. In August 1988, a series of successive radar surveys of long surface wave manifestations on the Pacific Ocean surface was carried out in the 3 cm wave range by means of an airborne X-band radar system “Analog”. The analysis of the results includes estimation of both spatial and frequency features of the detected long-wave packets and, also, a comparison of the measurement results with model calculations performed in the framework of theory of radio wave scattering by the sea surface in the presence of seismic wave effects.

Results. Radar images of wave packets of long surface waves in the open ocean have been obtained. From the imaging data, the spatial scale (5…10 km) of these waves, the lengths (1…5 km) of wave packet components and the wave packet velocity (6.1 m/s) have been derived. Analysis has been given to the nonlinear form of wave packet components, and their amplitudes have been estimated by comparing the experimental and theoretically obtained radio contrasts. The bathymetry of the surface-wave track has been performed to suggest that the observed wave packet represents a set of solitons generated by a seismic impact with the further underwater collapse. 

Conclusions. A possibility has been demonstrated for monitoring wave packets of long surface waves in their propagation dynamics. The experiments of the sort for gaining a deeper insight into the oceanatmosphere interaction physics can be conducted by means of not only airborne but also spaceborne radar systems with allowance made for the rate of surveys in both time and space.
Ключевые слова: radar method, seismic impact, soliton, surface wave packet

Manuscript submitted 22.06.2020
Radiofiz. elektron. 2021, 26(1): 3-11
Full text (PDF)

References: 

 

1. Tsunami - automated Internet system for the search and synthesis of physical principles of energy converters (in Russian). Available from: http://www.heuristic.su/effects/catalog/est/byId/ description/82/index.html
 
2. Filippov, A.T., 1990. Diversiform soliton. 2nd ed. Moscow: Nauka Publ. (in Russian).
 
3. Tsunami Warning System. Available from: http://www.typhoon.obninsk.ru/activities/prevention/ rsps.php
 
4. Matveyev, A.Ya., Velichko, S.A., Bychkov, D.M., Ivanov, V.K., Tsymbal, V.N., Yefimov, V.B., Gavrilenko, A.S., 2019. Multi-frequency and multi-angle radar methods application peculiarities for parameters estimation of oil pollutions on sea surface. Radiofiz. elektron., 24(3), pp. 30-44 (in Russian). DOI: https://doi.org/10.15407/rej2019.03.030
 
5. Boev, A.G., Boeva, A.A., Matveyev, O.Y., 2011. Radar Contrast of Wind Ripples on the Sea Wave of Seismic origin. Radio Physics and Radio Astronomy, 2(2), pp. 181-188.
https://doi.org/10.1615/RadioPhysicsRadioAstronomy.v2.i2.110
 
6. Boev, A.G., Matveyev, O.Y., Boeva, A.A., Bychkov, D.M., Efimov, V.B., Tsymbal, V.N., 2011. Radar contrast of wind ripples on the seismic origin wave. In: E.A. Loupian, ed. 2011. Sovr. Probl. DZZ Kosm., 8(4), pp. 177-189. Moscow: Space Research Institute RAS of Russian Federation Publ. (in Russian).
 
7. Landau, L.D., Lifshitz, E.M., 1958. Mechanics. Moscow: Fizmatlit Publ. (in Russian).
 
8. Boev, A.G., Efimov, V.B., Tsymbal, V.N. ed., Yatsevich, S.Ye., Kalmykov, I.A., Kurekin, A.S., Yemelyanov, O.L., Kavelin, .S., Saltykov, Yu.D., Kulikovsky, O.Yu., Popel, A.M., Matveyev, А.Ya., Yevdokimov, A.P., Kryzhanovsky, V.V., Bychkov, D.M., Sytnik, O.V., Gavrilenko, A.S., Konjukhov, S.N. ed., Dranovskii, V.I. ed., 2007. Radar methods and facilities for operational Earth remote sensing from airborne and spaceborne carriers. Kiev, NAS of Ukraine Publ. (in Russian).
 
9. Tsymbal, V., Mayveyev, A. eds., 2017. Radar monitoring of natural and anthropogenic hazardous phenomena. LAP LAMBERT Academic Publ.
 
10. Sychev, P.M. ed., 1980. Tectonics of Kuril-Kamchatka Trench. Moscow: Nauka Publ. (in Russian).
 
11. Earthquakes Catalogue for Kamchatka and the Commander Islands (1962 - present). Available from: http://sdis.emsd.ru/info/earthquakes/catalogue.php?out=info
 
12. Otnes, R.K., Enochson, L., 1978. Applied Time Series Analysis. Vol. 1. Basic Technologies. New York: Willey Publ.
 
13. NOAA National Centers for Environmental Information. Bathymetric Data Viewer. Available from: https:// maps.ngdc.noaa.gov/viewers/ bathymetry/
 
14. Gill, A.E., 1982. Atmosphere-Ocean Dynamics. Vol. 1. New York: Academic Press Publ.
 
15. Pelinovsky, E.N., ed. in chief, 1982. Effect of large-scale internal waves on the sea surface. Gorkii, IPF AN USSR Publ.
 
16. Korteweg, D.J., de Vries, G., 1895. On the Change of Form of Long Waves Advancing in a Rectangular Canal, and on a New Type of Long Stationary Waves. Phil. Mag., Ser. 5, 39(240), pp. 422-443. DOI: https://doi.org/10.1080/14786449508620739
 

17. Zeytounian, R.Kh., 1995. Nonlinear long waves on water and solitons. Phys. Usp., 38(12), pp. 1333-1381. DOI: https://doi.org/10.1070/PU1995v038n12ABEH000124