doi:https://doi.org/10.30898/1684-1719.2021.6.13

Zhurnal Radioelektroniki - Journal of Radio Electronics. eISSN 1684-1719. 2021. No. 6
Contents

Full text in Russian (pdf)

Russian page

DOI https://doi.org/10.30898/1684-1719.2021.6.13

UDC 537.872.32

Numerical simulation of the ground distribution of the field strength of an on-board low-frequency transmitter located in the ionosphere.

V. A. Moshkov

Kotelnikov Institute of Radioengineering and Electronics of the Russian Academy of Sciences, Mokhovaya str., 11-7, Moscow 125009, Russia

The paper was received on June 21, 2021

Abstract. Projects of active experiments in the ionosphere and the magnetosphere of the Earth and planets often include powerful low-frequency transmitters installed on-board of a spacecraft. Such sources are very effective, but their radiation is extremely heterogeneous in space because of the anisotropy of the ionospheric plasma due to the presence of the magnetic field of the Earth. This paper is devoted to numerical modeling of a distribution of the wave field strength near the Earth surface. The work examines a specific active wave experiment with a 20 m loop as a transmitting antenna. The satellite is assumed to orbit with an inclination of 82.5 degrees at an average altitude of 1000 km. All calculations are performed in linear approximation using the cold magneto-active plasma model. The computation model uses ray approximation everywhere except for the highly heterogeneous lower ionosphere, where a full wave equations set is applied. It is shown that the maximum magnetic field value is decreased with increasing of the geomagnetic latitude value and the strength range is 1… 2 nA/m for frequency 10 kHz and loop current 100 A. The magnitude of the vertical component of the electric field lies in the range of 0.4 ... 0.8 μV/m. An average Doppler frequency shift is equal to ~0.4 Hz. A comparison is made between the data of the numerical experiment and the results of simple estimations of the values of the magnetic field strength at the maximum of the ground distribution.

Key words: ionosphere, low frequencies, on-board loop transmitter, wave field’s strength distribution, Doppler frequency shift.

References

1. Moshkov A.V. Numerical simulation of measurements of an on-board low-frequency transmitter wave fields strength in the Ionosphere using a sub-satellite receiver. Zhurnal radioelektroniki [Journal of Radio Electronics]. 2020. No.5. https://doi.org/10.30898/1684-1719.2020.5.12 (In Russian).

2. Erukhimov L.M. Ionosphere as a space plasma laboratory. Sorosovskiy obrazovatelnyi zhurnal [Soros Educational Journal]. 1998. Vol.4. No.4. P.71-77. (In Russian)

3. Armand N.A., Semenov Y.P., Tchertok B.E. et al. An experimental study in the Earth’s Ionosphere of an ELF emission of a loop antenna situated onboard of the orbital complex ‘Mir-Progress-28-Souz TM-2’. Radiotechnica and Electronika [Radio Engineering and Electronics]. 1988. Vol. 33. No.11. P.2225-2233. (In Russian)

4. Moshkov A.V., Pozhidaev V.N. Numerical simulation of the distribution of the low-frequency field created by a transmitting loop antenna installed on board a spacecraft. J. of Communications Technology and Electronics. 2019. Vol.64. No.9. P.937-944. https://doi.org/10.1134/S1064226919080126

5. Gurevich A.V. Nonlinear effects in the Ionosphere. Physics – Uspekhi. 2007. Vol. 50. No. 11. PP. 1091–1121. https://doi.org/10.3367/UFNr.0177.200711a.1145

6. Konyukhov S.N., editor. Rakety i kosmicheskie apparaty konstruktorskogo buro “Yuzhnoye” [Rockets and Spacecraft of ‘Yuzhnoye’ Development Laboratory]. Dnepropetrovsk, 2000 [online resource]. The site owner: M.K. Yangel State Development Lab. "Yuzhnoye". URL: http://rvsn.ruzhany.info/umz_2000_00.html (accessed on June 16, 2021). (In Russian)

7. Moshkov A.V., Pozhidayev V.N. Distribution of the strength of the low-frequency field demodulated in the disturbed lower ionosphere over the earth surface. J. of Communications Technology and Electronics. 2018. Vol.63. No.5. P.413-419. https://doi.org/10.7868/S0033849418050030

8. Davies K. Ionospheric Radio Waves. Blaisdell Publ. Co. 1969. 460 p.

9. Makarov G.I., Novikov V.V. Problems in the Propagation of Superlong Radio Waves in the Earthionosphere Waveguide Channel. Sov. Phys. Usp.1970. Vol.12. No.4. P.581-583. https://doi.org/10.1070/PU1970v012n04ABEH004065.

10. Aksenov V.I, Moshkov A.V. On field intensity over the earth surface from a low frequency source placed in the ionosphere. Radiotechnika i Electronika [Radio Engineering and Electronics]. 1987. Vol.32. No 5. P 913-921. (In Russian)

11. Aksenov V.I, Moshkov A.V. Three dimension ray tracing of low frequency electromagnetic waves in the magnetosphere of the Earth. Kosmicheskie issledovania [Journal of Space Research]. 1981. Vol.19. No.6. P.876-883. (In Russian)

12. Budden K.G. Radio Waves in the Ionosphere. Cambridge: University Press. 1961. 542 p.

13. Moshkov A.V., Pozhidaev V.N. Numerical Simulation of Very-Low-Frequency Waves Passing through the Magnetoactive Plane-Layered Plasma of Earth's Lower Ionosphere. J. of Communications Technology and Electronics. 2020. Vol.65. No.5. P.472-479. https://doi.org/10.1134/S1064226920050101

14. Fatkullin M.N., Zelenova T.I., Kozlov V.K., Legenka A.D., Soboleva T.N. Empiricheskie modely sredneshirotnoy ionosfery. [Empirical models of the midlatitude ionosphere]. Мoscow. Nauka Publ. 1981. 256 p. (In Russian)

15. Moshkov A.V. Estimation of the field strength of a low-frequency ionospheric source in the vicinity of the main maximum of distribution on the Earth surface. J. Communications Technology and Electronics. 2009. Vol.54. No 12. P.1360-1365. https://doi.org/10.1134/S1064226909120043

For citation:

Moshkov A.V. Numerical simulation of the ground distribution of the field strength of an on-board low-frequency transmitter located in the ionosphere. Zhurnal Radioelektroniki [Journal of Radio Electronics]. 2021. No.6. https://doi.org/10.30898/1684-1719.2021.6.13 (In Russian)