Probability of erroneous reception of navigational radio signals under Ionospheric disturbances

Authors

  • Gakhova NN Department of applied informatics and information technologies, Belgorod State University, 85, Pobedy St., Belgorod, 308015, Russia
  • Pashintsev VP Department of applied informatics and information technologies, Belgorod State University, 85, Pobedy St., Belgorod, 308015, Russia
  • Katkov EK Department of information security of automated systems, North Caucasus Federal University, 1, Pushkin Street, Stavropol 355009, Russia
  • Zaytseva TV Department of information security of automated systems, North Caucasus Federal University, 1, Pushkin Street, Stavropol 355009, Russia
  • Balabanova TN Department of information security of automated systems, North Caucasus Federal University, 1, Pushkin Street, Stavropol 355009, Russia

Keywords:

satellite radio navigation systems, size of ionospheric inhomogeneities, artificial disturbances of the ionosphere, the probability of arising the frequency-selective fading, coherence band of the transionospheric channel

Abstract

The work deals with the issues of the determination of the probability of frequency-selective fading (FSF) of navigational radio signals in satellite radio navigation systems under artificial ionosphere disturbances. The connection between the coherence band of the trans-ionospheric channel and the conditional size of ionospheric inhomogeneities is established. Based on the results of computer simulation, the threshold values of the Mean square deviation (MSD) of fluctuations of the total electron content in the inclined radio-line are determined, in which the probability of frequency-selective fading is high. This study will enable improving the operation of the developed information system of the ionosphere monitoring.

References

. Carrano, C., Groves, K., 2007. TEC Gradients and Fluctuations at Low Latitudes Measured with High Data Rate GPS Receivers, ION 63 Annual Meeting, April 23-25, Cambridge(In Massachusetts):156 – 163.

. Katkov, K.A., Pashintsev, V.P., Katkov, E.K., Gahova, N.N., Gahov, R.P., Titov, A.I.,2017. Forecast accuracy of determining pseudo range in satellite navigation system through analysis of data from ionosphere monitoring. Journal of Fundamental and Applied Sciences, 9(1S): 899 – 913. Available online at http://www.jfas.info.

. Pashintsev, V.P., Katkov, K.A., Gahov, R.P. Malofey, O.P., Shevchenko V.A.,2012.Sputnikovayanavigaciyapriionosfernyhvozm ushcheniyah [Satellite navigation under ionosphere disturbances], NCSTU, Stavropol (In Russian).

. Katkov, K.A., Pashintsev, V.P.,Katkov, E.K.,2016. Information system of monitoring of the ionosphere.IzvestiyaSamarskogoNauchnogoCentra RAN, 18(2(3)): 907 – 912. (In Russian).

. Maslov, O.N.,Pashintsev, V.P., 2006.Modelitransionosfernyhradiokanalovipomekhoust ojchivost' sistemkosmicheskojsvyazi [Models of

transionospheric radio channels and noise immunity of space communication systems], PSATI, Samara (In Russian).

. Gelberg, M.G., 1986.Neodnorodnostivysokoshirotnojionosfery [Inhomogeneity of the high-latitude ionosphere], Science, Novosibirsk (In Russia)

. Kunitsyn, V.E., Padokhin, A.M., Vasiliev, A.E.,Kurbatov, G.A, Frolov, V.L., Komrakov, G.P.,2011. Study of GNSS-measured ionospheric total electron content variations generated by powerful HFheating. Advances in Space Research, 47: 1743–1749.

. Pashintsev, V.P., Chipiga, A.F., Cimbal, V.A.,Peskov M.V., 2016. The complex determining region of the ionosphere with small-scale inhomogeneities according to GPS monitoring.IzvestiyaSamarskogonauchnogocentra RAN, 18(2(3)): 941 – 945.(In Russian).

. Katkov, K.A., Pashintsev, V.P.,Katkov, E.K. 2016. Influence of parameters of the disturbed ionosphere to the error tracking phase, navigation radiosignal.Sovremennayanaukaiinnovacii, 2(14): 52 – 64.(In Russian).

. Pashintsev, V.P., Solchatov, M.E., Spirin, A.M., Katkov, K.A., 2007. Assessment of measurement error in the pseudo range of satellite navigation systems when the disturbances of the ionosphere in the Flayer, Fizikavolnovyhprocessoviradiotekhnicheskiesistemy, 10(6): 8 – 13.(In Russian).

. Shanmugam, S., Jones, J., MacAulay, A., Van Dierendonck, A.J.,2012. Evolution to Modernized GNSS Ionoshperic Scintillation and TEC Monitoring. Proceedings of IEEE/ION PLANS Myrtle Beach, South Carolina: 265 – 273.

. Blaunshteyn, N., Pulinec, S.A., Koen Ya, 2013. Calculation of main parameters of radio signals in the channel of the satellite – Earth during the propagation through the disturbed ionosphere, Geomagnetizmiaehronomiya, 53(2): 215 – 227.(In Russian).

. Carrano, C., Groves, K.,2006. The GPS Segment of the AFRL-SCINDA Global Network and the Challenges of Real-Time TEC Estimation in the Equatorial Ionosphere. Proceedings of ION NTM, Monterey: 1036 – 1047.

. Bogush, R.L., Juliano, F.U.,Nepp, D.L., 1981. Frequency-selective fading and their correction by the method of decisive feedback of high-speed satellite communication channels, TIIEHR, 71(6): 78 – 94.

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Published

2024-02-26

How to Cite

Gakhova, N. N., Pashintsev, V. P., Katkov, E. K., Zaytseva, T. V., & Balabanova, T. N. (2024). Probability of erroneous reception of navigational radio signals under Ionospheric disturbances. COMPUSOFT: An International Journal of Advanced Computer Technology, 8(06), 3201–3205. Retrieved from https://ijact.in/index.php/j/article/view/504

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Section

Original Research Article

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