T-Comm_Article 6_5_2021

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MATHEMATICAL MODEL OF THE RECEIVING PATH OF DIGITAL COMMUNICATION LINES

Vitaly G. Dovbnya, Southwest State University, Kursk, Russia, vit_georg@mail.ru

Dmitry S. Koptev, Southwest State University, Kursk, Russia, d.s.koptev@mail.ru

Abstract
Modern trends in the development of digital communication lines of fixed information transmission services, as well as the characteristics of continuous channels today determine the noise immunity of radio receiving systems. The main directions of its increase in terms of the radio receiving device as a whole and the demodulator device in particular are as follows: reducing the frequency and nonlinear distortions of the signal in the linear path, increasing the stability and purity of the spectral line of oscillations of local oscillators, increasing the selectivity for the mirror and combination channels of reception, compensation for intersymbol and cross – polarization interference, improving the functioning of the automatic gain control device (reducing static and dynamic errors), improving the quality of the functioning of the carrier wave recovery device and the clock synchronization device. Taking into account all of the above factors in order to increase the overall noise immunity of a digital communication line is a very difficult and urgent task, the solution of which must begin with the development of a mathematical model of a continuous digital communication line channel. This article discusses the radio receiving path of a digital communication line in an urban environment. The obtained analytical expressions are aimed at interpreting the processes of converting digital signals in the structural elements of radio receiving systems. The originality of the mathematical model developed in the article lies in the fact that it additionally, in comparison with similar models, takes into account the following number of factors: frequency instability and phase fluctuations of oscillations of the local oscillator synthesizer, dynamic and static errors in the operation of automatic gain control devices, carrier vibration recovery devices and devices clock synchronization of radio receiving systems of digital signals.

Keywords: mathematical model, radio receiving system, digital communication lines, demodulator device, carrier wave recovery device, frequency instability of local oscillator oscillations, clock synchronization device, potential noise immunity.

References

1. A.G. Zyuko (1983). Noise stability and efficiency of communication systems. Moscow: Communication. 320 p.
2. V.V. Zyablov, D.L. Korobkov, S.L. Portnoy (1991). High-speed message transmission in real channels. Moscow: Radio and communication. 288 p.
3. V.G. Kartashevsky. (2000). Processing of space-time signals in channels with memory. Moscow: Radio and communication. 272 p.
4. D. D. Klovsky (1982). Theory of transmission of discrete messages over radio channels. 2nd ed., Rev. and add. Moscow: Radio and communication, 1982. 302 p.
5. D. D. Klovsky (1973). Theory of signal transmission: textbook. for universities. Moscow: Communication. 376 p.
6. V.G. Dovbnya, V.E. Aziatsev, S.N. Mikhailov (2017). Noise immunity of radio receiving systems of digital communication lines: monograph. South-West. state un-t. Kursk. 175 p.
7. V.G. Dovbnya, D.S. Koptev (2020). Influence of the quality of heterodyne operation on the noise immunity of receiving signals with quadrature amplitude modulation. Radiotekhnika. Vol. 84. No. 9 (17).
   P. 40-48. DOI: 10.18127 / j00338486-202009 (17) — 03.
8. E. D. Viterbi (1970). Principles of coherent communication. Moscow: Sov.radio. 392 p.
9. V. I. Korzhik, L. M. Fink, K. N. Shchelkunov (1981). Calculation of noise immunity of systems of transmission of discrete messages: a reference book; ed. L. M. Fink. Moscow: Radio and communication. 232 p.
10. J. Forney (1973). Viterbi algorithm. TIIER. Vol. 61. No. 3.
    P. 12-25.
11. J. Stiffler (1975). Theory of synchronous communication. Moscow: Communication. 488 p.

Information about authors:

Vitaly G. Dovbnya, Doctor of Technical Sciences, Associate Professor, Professor of the Department of Space Instrumentation and Communication Systems, Southwest State University, Kursk, Russia
Dmitry S. Koptev,post-graduate student, lecturer at the Department of Space Instrumentation and Communication Systems, Southwest State University, Kursk, Russia