Article

Article title SCATTERING OF ELECTROMAGNETIC WAVES BY BODY OF REVOLUTION LOCATED ON MULTILAYERED HALF-SPACE
Authors S.G. Grishchenko, N.N. Kisel’, A.A. Vaganova
Section SECTION II. MATHEMATICAL MODELING OF RADIOPHYSICAL PROCESSES
Month, Year 11, 2013 @en
Index UDC 621.371.332.4
DOI
Abstract Radar and antennas problems of electromagnetic scattering by objects located on earth or water surface are very important. This paper deals with scattering of electromagnetic waves by body of revolution located on multilayered half-space, the roughness of the interfaces which satisfies the Raleigh criterion. The method of geometrical optics is used to solve the problem. Ray tracing in a multilayer media model are presented by directed segments, each of which has a geometric path of the ray between the two neighboring boundaries. The original recurrent algorithm of determination of rays multiply reflected between boundaries of the multilayered media and scattering in the interest direction is created and tested. Improvement of the geometrical optics solution is developed. Solution is considered curvature of boundaries of multilayered body of revolution and curvature of electromagnetic wave front in multilayered media. Algorithm of solving the problem is tested for multilayered objects located on the planelayered half-space as the model of the Earth surface.

Download PDF

Keywords Scattering of electromagnetic waves; multilayered Earth surface model; body of revolution.
References 1. Young R.P. Low scatter mirror degradation by particle contamination // Opt. Eng. – 1976. – Vol. 15. – P. 516-520.
2. Johnson B.R. Light scattering from a spherical particle on a conducting plane: i Normal incidence // J. Opt. Soc. Am. – 1992. – Vol. 9. – P. 1341-1351.
3. Lindell I.V., Sihvola A., Muinonen K., and Barber P. Scattering by small object close to an interface: I. Exact image theory formulation // J. Opt. Soc. Am. – 1991. – A 8. – Р. 472-476.
4. Chao J.C., Rizzo F.J., Elshafiey I., Liu Y.J., Upda L. and Martin P.A. General formulation for light scattering by a dielectric body near a perfectly conducting surface // J. Opt. Soc. Am. – 1996. – Vol. 13, № 2. – P. 338-344.
5. Bobbert P.A. and Vlieger J. Light scattering by a sphere on a substrate // Physica. – 1986. – Vol. 137. – P. 209-242.
6. Germer T.A. Light scattering by slightly nonspherical particles on surfaces // Opt. Lett. – 2002. – Vol. 27. – P. 1159-1161.
7. Eremin Y.A., Stover J.C. and Orlov N.V. Modeling scatter from silicon wafer features based on discrete sources method // Opt. Eng. – 1999. – Vol. 38. – P. 1296-1304.
8. Schmehl R., Nebeker B.M. and Hirleman E.D. Discrete-dipole approximation for scattering by features on surfaces by means of a two-dimensional fast Fourier transform technique // J. Opt. Soc. Am. – 1997. – Vol. 14. – P. 3026-3036.
9. Kim J.H., Ehrman S.H., Mulholland G.W. and Germer T.A. Polarized light scattering by dielectric and metallic spheres on silicon wafers // Appl. Opt. – 2002. – Vol. 41, № 25. – P. 5405-5412.
10. Назарчук З.Т. Численное исследование дифракции волн на цилиндрических структурах. – Киев: Наукова думка. – 1989. – 256 с.
11. Кочин В.Н., Литвиненко Л.Н., Просвирнин С.Л. Рассеяние волн цилиндром на границе раздела двух сред. Волны и дифракция -90. – М.: Физическое общество. – 1990. – Т. 1. – С. 270-273.
12. Butler Ch.M, Xu X.-B. and Glisson A. Current induced on a conducting cylinder located near the planar interface between two semi-infinite half-spaces // IEEE Trans. Antennas Propag. – 1990. – Т. 33, № 3. – P. 616-624.
13. Xu X.-B., Butler Ch.M. Current induced by TE exitation on a conducting cylinder located near the planar interface between two semi-infinite half-spaces // IEEE Trans. Antennas Propag. – 1986. – Т. 34, № 7. – P. 880-890.
14. Chen Q. and Wilton D.R. Electromagnetic scattering by three-dimensional arbitrary complex/conducting bodies // Antennas and Propagation Society International Symposium. – 1990. – Vol. 2. – P. 590-593.
15. Geng N. Electromagnetic scattering and radiation by surfaces of arbitrary shape in layered media, part i: Theory // IEEE Trans. Antennas Propag. – 2001. – Vol. 49, № 5. – Р. 740-748.
16. Michalski K.A. and Zheng D. Electromagnetic scattering and radiation by surfaces of arbitrary shape in layered media, part i: Theory // IEEE Trans. Antennas Propag. – 1990. – Vol. 38, № 3. – Р. 335-344.
17. Chang H.S., Mei K.K. and Pottier E. Scattering of electromagnetic waves by buried and partly buried bodies of revolution // IEEE Trans. Geosci. Remote Sens. – 1985. – Vol. 23, № 4. – P. 596-605.
18. Geng N. and Carin L. Fast multipole method for scattering from an arbitrary PEC target above or buried in a lossy half space // IEEE Trans. Antennas Propag. – 2001. – Vol. 49, № 5. – Р. 740-748.
19. Обидовский В.Г., Грищенко С.Г. Применение нормированных присоединенных полиномов Лежандра в задачах электродинамики // Рассеяние электромагнитных волн. Таганрог. – 1987. – Вып.6. – С. 136-139.
20. Marquart N.P., Molinet F. and Pottier E. Investigation on the polarimetric behavior of a target near the soil // IEEE Trans. Geosci. Remote Sens. – 2006. – Vol. 44, № 10. – P. 1-9.
21. Marquart N.P., Molinet F. and Pottier E. A refined GTD ray system for an embedded object and its polarimetric behavior // IEEE Trans. Geosci. Remote Sens. – 2008. – Vol. 46, № 9. – P. 2538-2546.
22. Панычев А.И. Алгоритм трехмерной трассировки радиоволн локальной беспроводной сети // Известия ЮФУ. Технические науки. – 2012. – № 11 (136). – С. 31-41.
23. Grishchenko S.G. , Kisel′ N.N. Quasy-optical Simulation of Multilayer Objects in the Problems of the Electromagnetism // Proc. 3 Chaotic Modeling and Simul. Int. Conf. Greece. – 2010.
– CHAOS2010 Proc. on-line http://www.cmsim.net/sitebuildercontent/sitebuilderfiles/ Grish-
chenko_Kisel-Quasy-optic_simulation_of_multilayer_objects-CHAOS2010-Paper.pdf.
24. Cai-Cheng Lu, Chew W.C. Multilevel Fast Multipole Algorithm for Electromagnetic Scattering by Large Complex Objects // IEEE Trans. Antennas Propag. – 1997. – Vol. 45, № 10. – P. 1488-1493.
25. Грищенко С.Г. Рассеяние электромагнитной волны на теле вращения с многослойным покрытием в квазиоптической области // Радиотехника и электроника. – 1993. – Т. 38, № 8. – С. 1370-1378.

Comments are closed.