Development of a complex mathematical model of the state of a channel of multi-antenna radio communication systems

Authors

DOI:

https://doi.org/10.15587/1729-4061.2019.166994

Keywords:

radio communication devices, Jakes model, Doppler spectrum, computational complexity, constellation matrix, noise immunity

Abstract

The complex mathematical model of the state of the channel of multi-antenna radio communication systems is developed. The model takes into account: the effect of intentional noise and signal fading, the number of receiving antennas, Doppler effect, correlation coefficient, speed and direction of the receiver and the transmitter, intersymbol interference, phase jitter and inclination of the constellation matrix. Simulation of the state of the channel of multi-antenna radio communication systems is carried out for each individual antenna channel, after which a generalized estimate is formed at the output. The development of the proposed integrated mathematical model is due to the need to improve the accuracy of the description of the channel state of multi-antenna radio communication systems with an acceptable computational complexity. The proposed model allows to improve the accuracy of the description of the state of the channel of multi-antenna radio communication systems by taking into account additional destabilizing factors, thereby increasing the accuracy of the channel state assessment. I would like to note that at the same time there is an increase in the computational complexity at the level of 5-7% due to an increase in the number of evaluated indicators. The mentioned complex mathematical model should be used in radio stations with a programmable architecture to increase their noise immunity by increasing the accuracy of the evaluation of the characteristics of the receiving and transmitting path relative to the state of the channel. The research of the correlation between antennas of multi-antenna radio communication systems was conducted. The results show that in the presence of a line of sight between the receiver and the transmitter, the signal correlation is high and therefore a small increase is expected from the use of several antennas, and in the absence of line of sight conditions, the signal correlation is low

Author Biographies

Svitlana Kalantaievska, Military Institute of Telecommunications and Informatization named after Heroes of Kruty Moskovska str., 45/1, Kyiv, Ukraine, 01011

Adjunct

Department of Scientific and Organizational

Oleksii Kuvshynov, Ivan Chernyakhovsky National Defense University of Ukraine Povitrofloskyi ave., 28, Kyiv, Ukraine, 03049

Doctor of Technical Sciences, Professor, Deputy Chief

Educational-Scientific Institute

Andrii Shyshatskyi, Central Scientific Research Institute of Armament and Military Equipment of the Ukrainian Armed Forces Povitrofloski ave., 28, Kyiv, Ukraine, 03049

PhD, Head of Research Laboratory

Research Laboratory of Electronic Warfare Development

Olha Salnikova, Ivan Chernyakhovsky National Defense University of Ukraine Povitrofloskyi ave., 28, Kyiv, Ukraine, 03049

Doctor of Public Administration, Senior Researcher, Head of Educational and Research Center

Educational and Research Center of Strategic Communications in the Sphere of National Security and Defense

Yurii Punda, Ivan Chernyakhovsky National Defense University of Ukraine Povitrofloskyi ave., 28, Kyiv, Ukraine, 03049

Doctor of Military Sciences, Senior Researcher, Head of Department

Department of Strategy National Security and Defence

Pavlo Zhuk, Ivan Chernyakhovsky National Defense University of Ukraine Povitrofloskyi ave., 28, Kyiv, Ukraine, 03049

PhD, Associate Professor, Head of Scientific Center

Scientific Center for the Prevention of Security and Defense Corruption

Olesia Zhuk, Military Institute of Telecommunications and Informatization named after Heroes of Kruty Moskovska str., 45/1, Kyiv, Ukraine, 01011

PhD, Associate Professor, Leading Researcher

Scientific Department

Hryhorii Drobakha, National Academy of the National Guard of Ukraine Zakhysnykiv Ukrainy sq., 3, Kharkiv, Ukraine, 61001

Doctor of Military Sciences, Professor, Chief Researcher

Research Center Service and Combat Activity

Lyubov Shabanova-Kushnarenko, National Technical University “Kharkiv Polytechnic Institute” Kyrpychova str., Kharkiv, Ukraine, 61002

PhD, Senior Lecturer

Department of Intelligent Computer Systems

Sergii Petruk, Central Scientific Research Institute of Armament and Military Equipment of the Ukrainian Armed Forces Povitrofloski ave., 28, Kyiv, Ukraine, 03049

Deputy Chief of Research Department

Research Department of Development of Anti-Aircraft Missile Systems and Complexes

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Published

2019-05-13

How to Cite

Kalantaievska, S., Kuvshynov, O., Shyshatskyi, A., Salnikova, O., Punda, Y., Zhuk, P., Zhuk, O., Drobakha, H., Shabanova-Kushnarenko, L., & Petruk, S. (2019). Development of a complex mathematical model of the state of a channel of multi-antenna radio communication systems. Eastern-European Journal of Enterprise Technologies, 3(9 (99), 21–30. https://doi.org/10.15587/1729-4061.2019.166994

Issue

Vol. 3 No. 9 (99) (2019): Information and controlling system

Section

Information and controlling system

License

Copyright (c) 2019 Svitlana Kalantaievska, Oleksii Kuvshynov, Andrii Shyshatskyi, Olha Salnikova, Yurii Punda, Pavlo Zhuk, Olesia Zhuk, Hryhorii Drobakha, Lyubov Shabanova-Kushnarenko, Sergii Petruk

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