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DOI
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Języki publikacji
Abstrakty
This paper substantiates the method of polarization selection of navigation objects located in the zone of atmospheric formations (i.e., precipitation of different intensity and phase state), based on polarization differences in the parameters of their echo signals in a partially polarized electromagnetic wave arriving at the input of the all-polarized antenna of the ship radar polarization complex (SRPC). The partially polarized wave is represented as consisting of two polarized streams with polarization degrees m1 and m2 corresponding to the echo signals of the navigation object and atmospheric formation. The property of the partially polarized electromagnetic wave reflected from a complex object (i.e., navigation object located in the zone of atmospheric formation) is represented by real energy polarization Stokes parameters having intensity dimension. The scattering ability of the complex object is represented by the Mueller scattering matrix, the elements of which are measured by SRPC when it is sequentially irradiated with electromagnetic waves of four fixed polarizations. Polarization selection of navigation objects located in the zone of atmospheric formations uses the difference of polarization degrees of echo signals of the navigation object and atmospheric formation. The process of selection of the navigation object echo signal from the echo signal of the complex object and its observation on the screen of the SRPC indicator or computer display is based on the relationship between the degree of polarization of the electromagnetic wave and the polarization parameters of the navigation object echo signal and the atmospheric formation. The aim of this research is to develop polarization criteria of optimality of radar parameters of echo signals of partially polarized electromagnetic waves, represented by polarization degrees m1 and m2 corresponding to the navigational object and atmospheric formation observed by SRPC. As a result of the performed research, the problem of polarization selection of navigation objects located in the zone of atmospheric formations along the ship’s trajectory according to the values of the polarization degree of the navigation object echo signal is solved.
Rocznik
Tom
Strony
17--22
Opis fizyczny
Bibliogr. 18 poz., tab.
Twórcy
autor
- National University “Odessa Maritime Academy” 8 Didrikhsona St, 65000 Odesa, Odesa Oblast, Ukraine
Bibliografia
- 1. Antifeev, V.N., Borzov, A.B. & Suchkov, V.B. (2003) Physical models of radar scattering fields of objects of complex shape. Moscow: Bauman Moscow State Technical University.
- 2. Atamaniuk, V.V. (2015) Modelling of scattering fields of distributed radar objects and scenes. Scientific Bulletin of the National Technical University of Ukraine 25(8), pp. 299–306.
- 3. Barton, D.K. (2005) Radar System Analysis and Modeling. Boston, London: Artech House.
- 4. Barton, D.K. (2013) Radar Equations for Modern Radar. Boston, London: Artech House.
- 5. Bogdanov, V.I., Ivanov, V.A., Pyatakovich, V.A. & Yushkov, I.I. (2002) Recognition of marine objects of surface and underwater type using the method of fuzzy inference. Proceedings of the X All-Russian Seminar “Neuroinformatics and its Applications”.
- 6. Bringi, V.N. & Chandrasecar, V. (2002) Polarimetric Doppler Weather Radar. Cambridge University Press, doi: 10.1017/CBO9780511541094.
- 7. Dikul, O.D., Luchin, A.A., Trufanov, E.Yu., Hrabrostin, B.V. & Hrabrostin, D.B. (2005) Target recognition based on the results of radar measurements in a complex noise environment. Journal of Radiotekhnika 11, pp. 34–39.
- 8. Gavrilenko, V.G. (2000) Radio wave propagation in modern mobile communication systems. Nizhny Novgorod, Lobachevsky NNGU.
- 9. Gorshkov, S.A., Latushkin, V.V., Latushkin, S.Yu. & Sedyshev, S.Y. (2004) Fundamentals of radiolocation. Lecture Notes. Part 2. Minsk: VA RB.
- 10. Gorshkov, S.A., Orgish, P.I. Bujlov, E.N. & Filchuk, Yu.S. (2014) Refined methodology for calculating the range of pulsed radars on the background of masking interference. Journal of Applied Radioelectronics 13 (1), pp. 3–9.
- 11. Jeruchim, M.C., Balaban, P. & Shanmugan, K.S. (2002) Simulation of Communication Systems. 2nd Edition. New York, Kluwer Academic, Plenum, pp. 545–591.
- 12. Kolyadov, D.V. (2001) Analysis of the influence of polarisation characteristics of targets on their distinguishability. Scientific Bulletin of MSTU GA, Radiophysics and Radio Engineering 36, pp. 69–97.
- 13. Kulemin, G.P. (2003) Millimeter-Wave Radar Targets and Clutter. Boston, London: Artech House.
- 14. Piza, D. M. & Zalevskij, A. P. (2005) Peculiarities of adaptation of spatial filters under the influence of combined disturbances. Journal of Radio Electronics, Computer Science, Control 1, pp. 45–48.
- 15. Piza, D.M., Zalevskij, A.P. & Sirenko, A.S. (2013) The influence of jamming signal interference on pulse-doppler radar electronic counter-countermeasures. Journal of Radio Electronics, Computer Science, Control 1, pp. 51–54, doi: 10.15588/1607-3274-2013-1-8.
- 16.S hirman, YA.D. (2007) Radioelectronic Systems: Fundamentals of Construction and Theory. Reference book. 2nd Ed., Moscow, Radiotehnika.
- 17. Verdenskaya, N.V., Ivanova, I.A. & Sazonov, V.V. (2009) Modelling of detection algorithms at different types of polarization reception. Report no. 1995. Moscow: JSC “Radio Engineering Institute named after Academician A.L. MINTS”.
- 18. Zajcev, D.V. (2012) Multi-position radar systems. Methods and algorithms of information processing in the interference conditions. Bulletin of Nizhny Novgorod University, Radiophysics 3, pp. 60–64.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-05a739a9-790f-4b07-99b2-78b9633151f6