SIMULATION OF INTERACTION OF ELECTROMAGNETIC WAVES WITH ANISOTROPIC MEDIA UNDER HYDROCARBON DEPOSITS IN THE MODE OF VIDEO-PULSE SIGNALS

The article presents the simulation of the interaction of electromagnetic waves in the mode of video pulse signals with the medium over hydrocarbon deposits. The analysis of the spectra of reflected video pulse signals from the medium over hydrocarbons is carried out. A study of the propagation of radio waves over hydrocarbons is carried out within the framework of a quasihydrodynamic approximation. The choice of the frequencies of video pulse signals is due to the determination of media characteristics over deposits at great depths compared to the surface of the earth. The spectrum of reflected signals from an anisotropic medium above a hydrocarbon deposit in the mode of video pulse signals can be used to determine the electrodynamic characteristics of the medium over the deposit over a wide range of frequencies of probed signals, dielectric permittivities and conductivity of media. The ability to reconfigure a geo-prospecting device from one mode to another (pulse width adjustment) in the presence of a deposit complements the functionality to search for hydrocarbon deposits. Electromagnetic methods for the search for and identification of hydrocarbons can be improved by obtaining information about objects through several information channels, which allows them to be identified with a sufficiently high level of reliability on the background of the underlying environment. The depths of occurrence, the resolving power in the investigated frequency range are determined. The results of the research can be used to develop new electromagnetic methods for the search for hydrocarbon deposits.

1. Moskvichew V. N. Interraction of electromagnetic waves (EMW) with anisotropic inclusion in communication line. 9th Microwave Conference “NICON-91”, Rydzyna, May 20–22, 1991. Rydzyna, 1991, vol. 1, pp. 240–244.

2. Gololobov D. V., Yanushkevich V. F. Radio search and identification systems for hydrocarbon deposits in two-frequency interaction mode. Vestsi Natsyyanal’nai akademii navuk Belarusi. Seryya fizika-technichnych navuk = Proceedings of the National Academy of Sciences of Belarus. Physical-technical series, 2002, no. 1, pp. 4954 (in Russian).

3. Gololobov D. V., Tsyivis K. V., Yanushkevich V. F. Surface impedance of the hydrocarbon deposit interaction in a two-frequency mode. Izvestiya Belorusskoy inzhenernoy akademii [Proceedings of the Belarusian Engineering Academy], 2001, no. 1 (11), pp. 101104 (in Russian).

4. Gololobov D. V., Yanushkevich V. F., Kalintsev S. V. Surface impedance of the medium above the hydrocarbon deposits in frequency mode-modulated signals. Vestsi Natsyyanal’nai akademii navuk Belarusi. Seryya fizika-technichnych navuk = Proceedings of the National Academy of Sciences of Belarus. Physical-technical series, 2010, no. 4, pp. 98101 (in Russian).

5. Moskvichew V. N. Investigation of the interaction of electromagnetic waves with a hydrocarbon deposit. Radiotekhnika i elektronika. Resp. mezhved. sb. [Radio engineering and electronics: Republican interdepartmental collection]. Minsk, Vysheishaya shkola, 1989, iss. 18, pp. 91‒96 (in Russian).

6. Adamovskiy E., Yanushkevich V. Simulation of electromagnetic waves interaction with hydrocarbon deposits. 8 Junior Researchers Conference European and National Dimension in Research. Part 3. Technology. Novopolotsk, Polotsk State University, 2016, pp. 179–183.

7. Yanushkevich V. F., Kremenya K. I., Ivanov M. M., Maladzechkina T. V. Interaction of electromagnetic waves with anisotropic environments over hydrocarbonic deposits in the mode of radio pulse signals. Vestnik Polotskogo gosudarstvennogo universiteta. Fundamentalnyie nauki. Fizika [Proceedings of the Polotsk State University. Fundamental sciences. Physics], 2016, no. 12, pp. 45–50 (in Russian).

8. Ivanova K. I., Yanushkevich V. F. Geoelectrical exploration method of hydrocarbon deposits using radio pulse signals. Materialy XV mezhdunarodnoy nauchno-prakticheskoy konferentsii “Fundamentalnyie i prikladnyie issledovaniya v sovremennom mire”, Sankt-Peterburg, 4 okt. 2016 g. T. 1 [Proceedings of the XV International Scientific and Practical Conference “Fundamental and applied research in the modern world”, Saint-Petersburg, 4 October 2016 g. Vol. 1]. Saint Petersburg, 2016, pp. 107–111 (in Russian).

9. Gribik Ya. G. Signs of manifestation of the modern accumulation of hydrocarbons in the conditions of the Pripyat Trough. Materialy mezhdunarodnoy nauchno-prakticheskoy konferentsii “Potentsial dobyichi goryuchih iskopaemyih v Belarusi i prognoz ego realizatsii v pervoy polovine ХХI veka” [Proceedings of the international scientific-practical conference “The potential of mining of fossil fuels in Belarus and the forecast of its implementation in the first half of the 21st century”]. Gomel, Polespechat' Publ., 2012, pp. 275–280 (in Russian).

10. Shkarofsky I. P. New representations of dielectric tensor elements in magnetized plasma. Journal of Plasma Physics, 1986, vol. 35, iss 2, pp. 319–331. https://doi.org/10.1017/S0022377800011363

11. Finkelshteyn M. I., Kutev V. A., Zolotorev V. P. The use of radar subsurface sounding in engineering geology. Moscow, Nedra Publ., 1986. 182 p. (in Russian).