Development of a method for estimating the effect of transformation of the normalized frequency mismatch function of a coherent bundle of radio pulses on the quality of radar frequency resolution

Authors

DOI:

https://doi.org/10.15587/1729-4061.2021.238155

Keywords:

coherent bundle of radio pulses, resolution, mismatch function, phase fluctuations

Abstract

The necessity of studying the influence of the transformation of the frequency mismatch function of a coherent bundle of radio pulses on the quality of solving the radar frequency resolution problem is substantiated. This solution determines the effectiveness of radar observation of high-speed and maneuvering individual and group aerodynamic objects. The method is based on explicit expressions for calculating the normalized frequency mismatch function of a coherent bundle of radio pulses, taking into account its transformation due to the radial motion of high-speed and maneuvering individual and group aerodynamic objects. The estimation of the potential frequency resolution of bundles with different numbers of radio pulses with typical parameters for a coherent pulse radar is carried out. Possible values of frequency resolution under the additive effect of uncorrelated internal noise of the radar receiver and the multiplicative effect of correlated phase fluctuations of the radar signal are estimated. With an insignificant multiplicative effect of correlated phase fluctuations, a twofold increase in the number of radio pulses in a bundle provides an improvement in the frequency resolution (reduction of the width of the normalized frequency mismatch function) by 100 %. With the predominant multiplicative effect of these fluctuations, a twofold increase in the number of radio pulses results in an improvement in the frequency resolution by about 40 %. The developed method is of great theoretical and practical importance for the further development of the radar theory of high-speed and maneuvering individual and group aerodynamic objects.

Author Biographies

Serhii Yevseiev, Simon Kuznets Kharkiv National University of Economics

Doctor of Technical Science, Professor

Department of Cybersecurity and Information Technology

Oleksandr Kuznietsov, Ivan Kozhedub Kharkiv National Air Force University

PhD, Associate Professor
Department of Physics and Radioelectronics

Oksana Biesova, Ivan Kozhedub Kharkiv National Air Force University

PhD, Senior Researcher

Air Force Science Centre

Dmytro Kyrychenko, Ivan Kozhedub Kharkiv National Air Force University

Department of Combat Application of Anti-Aircraft Missile Systems

Olena Lukashuk, Ivan Kozhedub Kharkiv National Air Force University

PhD

Department of Physics and Radioelectronics

Stanislav Milevskyi, Simon Kuznets Kharkiv National University of Economics

PhD, Associate Professor

Department of Cybersecurity and Information Technology

Serhii Pohasii, Simon Kuznets Kharkiv National University of Economics

PhD, Associate Professor

Department of Cybersecurity and Information Technology

Iryna Husarova, Kharkiv National University of Radio Electronics

PhD, Associate Professor

Department of Applied Mathematics

Anna Goloskokova, National Technical University “Kharkiv Polytechnic Institute”

PhD, Associate Professor

Department of Software Engineering and Management Information Technologies

Volodymyr Sobchenko, National Academy of the State Border Guard Service of Ukraine Named after Bohdan Khmelnitsky

PhD

References

  1. Shirman, Ya. D. (Ed.) (2007). Radioelektronnye sistemy: osnovy postroeniya i teoriya. Moscow: Radiotekhnika, 512.
  2. Melvin, W. L., Scheer, J. A. (2012). Principles of Modern Radar: Advanced techniques. IET. doi: https://doi.org/10.1049/sbra020e
  3. Zohuri, B. (2020). Fundaments of Radar. Radar Energy Warfare and the Challenges of Stealth Technology, 1–110. doi: https://doi.org/10.1007/978-3-030-40619-6_1
  4. Klemm, R., Nickel, U., Gierull, C., Lombardo, P., Griffiths, H., Koch, W. (Eds.) (2017). Novel Radar Techniques and Applications Volume 1: Real Aperture Array Radar, Imaging Radar, and Passive and Multistatic Radar. IET. doi: https://doi.org/10.1049/sbra512f
  5. Herasimov S., Roshchupkin E., Kutsenko V., Riazantsev, S., Nastishin, Yu. (2020). Statistical analysis of harmonic signals for testing of Electronic Devices. International Journal of Emerging Trends in Engineering Research, 8 (7), 3791–3798. doi: https://doi.org/10.30534/ijeter/2020/143872020
  6. Kovalchuk, A., Oleshchuk, M., Karlov, V., Karpenko, O., Biesova, O., Lukashuk, O. (2021). Analysis of sensitivity of target tracking systems to external interference in multichannel radars with fixed parameters. Advanced Information Systems, 5 (1), 82–86. doi: https://doi.org/10.20998/2522-9052.2021.1.11
  7. Savchenko, V., Laptiev, O., Kolos, O. et. al. (2020). Hidden Transmitter Localization Accuracy Model Based on Multi-Position Range Measurement. 2020 IEEE 2nd International Conference on Advanced Trends in Information Theory (IEEE ATIT 2020) Conference Proceedings. Kyiv, 246–251.
  8. Barton, D. K. (2012). Radar Equations for Modern Radar. Artech House, 264.
  9. Herasimov, S., Belevshchuk, Y., Ryapolov, I., Volkov, A., Borysenko, M., Tokar, O. (2020) Modeling technology of radar scattering of the fourth generation EF-2000 Typhoon multipurpose aircraft model. International Journal of Emerging Trends in Engineering Research, 8 (9), 5075–5082. doi: https://doi.org/10.30534/ijeter/2020/30892020
  10. Minervin, N. N., Karlov, D. V., Konovalov, V. M. (2013). Features of influencing the ionosphere on radar signals at accelerated motion of space objects. Applied Radio Electronics, 12 (4), 530–532.
  11. Karlov, V., Kuznietsov, O., Belousov, V., Tuzikov, S., Oleschuk, M., Petrushenko, V. (2021). Accuracy of measurement of aerodynamic objects angular coordinates under tropospheric refraction conditions. Control, Navigation and Communication Systems, 1 (63), 146–152. doi: https://doi.org/10.26906/sunz.2021.1.146
  12. Volosyuk, V. K., Gulyaev, Y. V., Kravchenko, V. F., Kutuza, B. G., Pavlikov, V. V., Pustovoit, V. I. (2014). Modern methods for optimal spatio-temporal signal processing in active, passive, and combined active-passive radio-engineering systems. Journal of Communications Technology and Electronics, 59 (2), 97–118. doi: https://doi.org/10.1134/s1064226914020090
  13. Klochko, V. K. (2016). Algorithms of 3D radio-wave imaging in airborne Doppler radar. Radioelectronics and Communications Systems, 59 (8), 335–343. doi: https://doi.org/10.3103/s0735272716080021
  14. Karlov, V. D., Radiukov, A. O., Pichuhin, I. M., Karlov, D. V. (2015). Statistical descriptions of radio-location signals, reflected from local objects in the conditions of anomalous refraction. Science and Technology of the Air Force of Ukraine, 4 (21), 71–74.
  15. Karlov, V., Kuznietsov, O., Artemenko, A., Karlov, A. (2019). Evaluation of the accuracy of measuring the radial velocity of a target with an exponential and alternating decrease in phase correlation of the burst radio signal. Advanced Information Systems, 3 (1), 71–75. doi: https://doi.org/10.20998/2522-9052.2019.1.12
  16. Kuznietsov, O., Karlov, V., Karlov, A., Kiyko, A., Lukashuk, O., Biesova, O., Petrushenko, M. (2020). Estimation of the Dispersion of the Error in Measuring the Frequency of a Pack with Correlated Fluctuations in the Initial Phases of its Radio Pulses. 2020 IEEE Ukrainian Microwave Week (UkrMW). doi: https://doi.org/10.1109/ukrmw49653.2020.9252588
  17. Sedyshev, Yu., Atamanskiy, D. (2010). Radioelektronnye sistemy. Kharkiv: Kharkivskyi unyversytet Povitrianykh Syl, 418.
  18. Minervin, N. N., Vasyuta, K. S. (2013). Measure of angular resolution capability and measuring accuracy of a wave arrival corner in the presence of irregular distortions of its front and additive noise. Applied Radio Electronics, 12 (4), 484–486.
  19. Mogyla, A. A. (2014). Application of stochastic probing radio signals for the range-velocity ambiguity resolution in doppler weather radars. Radioelectronics and Communications Systems, 57 (12), 542–552. doi: https://doi.org/10.3103/s0735272714120036
  20. Herasimov, S. (2020). Aircraft flight route search method with the use of cellular automata. International Journal of Advanced Trends in Computer Science and Engineering, 9 (4), 5077–5082. doi: https://doi.org/10.30534/ijatcse/2020/129942020
  21. Yevseiev, S., Kuznietsov, O., Herasimov, S., Horielyshev, S., Karlov, A., Kovalov, I. et. al. (2021). Development of an optimization method for measuring the Doppler frequency of a packet taking into account the fluctuations of the initial phases of its radio pulses. Eastern-European Journal of Enterprise Technologies, 2 (9 (110)), 6–15. doi: https://doi.org/10.15587/1729-4061.2021.229221

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Published

2021-08-30

How to Cite

Yevseiev, S., Kuznietsov, O., Biesova, O. ., Kyrychenko, D., Lukashuk, O., Milevskyi, S., Pohasii, S., Husarova, I., Goloskokova, A., & Sobchenko, V. (2021). Development of a method for estimating the effect of transformation of the normalized frequency mismatch function of a coherent bundle of radio pulses on the quality of radar frequency resolution . Eastern-European Journal of Enterprise Technologies, 4(4(112), 13–22. https://doi.org/10.15587/1729-4061.2021.238155

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Section

Mathematics and Cybernetics - applied aspects