Abstract
The authors propose a new method for mathematical modeling of detecting tactical radio by adversary signal intelligence system. The method is based on the apparatus of tensor calculus with regard for the features of new-generation signal intelligence systems. The method is intended for evaluating the radio deception level of tactical radio system in providing the required radio deception level.
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References
Yu. K. Men’shakov, Types and Tools of Foreign Technical Reconnaissance [in Russian], Izd. MGTU im. Baumana, Moscow (2009).
S. I. Makarenko, M. S. Ivanov, and S. A. Popov, Noise Immunity of Communication Systems with Pseudorandom Tuning of Operating Frequency [in Russian], Svoe Izd., St.-Petersburg (2013).
A. I. Kupriyanov and A. V. Sakharov, Theoretical Fundamentals of Radio-Electronic Combat [in Russian], Vuzovskaya Kniga, Moscow (2007).
V. V. Tsvetnov, V. P. Dyomin, and A. I. Kupriyanov, Radio-Electronic Combat: Radio Deception and Anti-Jam [in Russian], Izd. MAI, Moscow (1999).
A. I. Palii, Radio-Electronic Combat (Tools and Techniques of Suppression and Security of Radio-Electronic Systems) [in Russian], Voenizdat, Moscow (1981).
V. A. Vartanesyan, E. Sh. Goikhman, and M. I. Rogatkin, Radio Direction Finding [in Russian], Voenizdat, Moscow (1966).
Z. M. Kanevskii, V. P. Litvinenko, and G. V. Makarov, Secrecy Theory, Pt. 1, Fundamentals of the Secrecy Theory [in Russian], Voronezh. Gos. Tekh. Univer., Voronezh (2003).
G. I. Tuzov (ed.), V. A. Sivov, V. I. Prytkov, et al., Noise Immunity of Radio Systems with Complex Signals [in Russian], Radio i Svyaz’, Moscow (1985).
L. E. Varakin, Communication Systems with Noise-Like Signals [in Russian], Radio i Svyaz’, Moscow (1985).
L. D. Landau and E. M. Lifshits, A Brief Course in Theoretical Physics, Book 1: Mechanics. Electrodynamics [in Russian], Glav. Red. Fiz.-Mat. Lit., Moscow (1969).
E. G. Zelkin and V. G. Sokolov, Methods of Antenna Synthesis: Phased Antenna Arrays and Antennas with Continuous Aperture [in Russian], Sov. Radio Moscow (1980).
A. P. Volobuiev, D. A. Bukhal, and A. V. Sergienko, “Mathematical modeling of detection, by adversary signal intelligence system, of tactical radio system with noise-like signals on the basis of phase modulation by pseudorandom sequence,” in: A Collection of Scientific Papers of VITI, Military Institute of Telecommunications and Information, No. 3, 32–40 (2017).
A. P. Volobuiev and D. A. Bukhal, “Mathematical modeling of detection, by a tactical radio system, of adversary signal intelligence system, which applies noise-like signals with a discrete frequency modulation by a pseudorandom sequence,” in: Modern Information Technologies in Security and Defense, Ivan Chernyakhovskii National University of Defense of Ukraine, No. 2 (29), 9–15 (2017).
A. P. Volobuiev, O. A. Usachova, and D. A. Bukhal, “Mathematical modeling of detection, by adversary signal intelligence system, of tactical radio system, which applies noise-like signals with frequency-phase modulation by pseudorandom sequence,” Nauka i Tekhnika Vozdushnykh Vooruzhennykh Sil Ukrainy, Ivan Kozhedub National University of Kharkiv, No. 3 (28), 76–85 (2017).
J. L. Alpert, V. L Ginzburg, and E. L. Feinberg, Propagation of Radio Waves [in Russian], Gos. Tekh. Izd. Tekhn.-Teoret. Lit-ry, Moscow (1953).
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Translated from Kibernetika i Sistemnyi Analiz, No. 3, May–June, 2018, pp. 131–140.
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Svida, I.Y., Volobuiev, A.P. & Bukhal, D.A. The Method of Mathematical Modeling of Tactical Radio Finding by Adversary Signal Intelligence. Cybern Syst Anal 54, 456–464 (2018). https://doi.org/10.1007/s10559-018-0046-8
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DOI: https://doi.org/10.1007/s10559-018-0046-8