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Volume 13 | Issue 5 | Year 2026 | Article Id. IJEEE-V13I5P109 | DOI : https://doi.org/10.14445/23488379/IJEEE-V13I5P109

Model of the Excitation Process of Chaotic Modes in Radio Electronic Devices Under the Influence of Fractalized Signals of Various Structures

Oleksandr Fyk, Stanislav Nikul, Oleksandr Florin, Oleg Nazarenko, Olena Novykova, Pavlo Bordiian,Dmytro Kosov

Received Revised Accepted Published
17 Feb 2026 16 Mar 2026 15 Apr 2026 30 May 2026

Citation :

Oleksandr Fyk, Stanislav Nikul, Oleksandr Florin, Oleg Nazarenko, Olena Novykova, Pavlo Bordiian,Dmytro Kosov, "Model of the Excitation Process of Chaotic Modes in Radio Electronic Devices Under the Influence of Fractalized Signals of Various Structures," International Journal of Electrical and Electronics Engineering, vol. 13, no. 5, pp. 105-117, 2026. Crossref, https://doi.org/10.14445/23488379/IJEEE-V13I5P109

Abstract

Usually, when describing the impact of signals, the informational approach and the thermal analysis approach are applied separately. This is due to the fact that the tasks of information suppression and thermal damage caused by high-power signals have traditionally been considered independently. However, in the case of using complex fractalized destructive signals, it is justified to apply an integrated approach. In particular, it is reasonable to employ not only a model describing the process of response formation of a radio-engineering system to low-amplitude electromagnetic information signals with a chaotic temporal structure, but also to assess, from the standpoint of the thermodynamic formalism, the possibility of the emergence of destructive chaotic regimes in the electrical circuits of radio-engineering systems. The object of the study is the process of propagation of fractalized destructive signals through the electrical circuits of radio-engineering systems. The article presents the results of the study on the processes leading to the emergence of chaotic regimes in the receiving path of radio-electronic devices under the influence of an electromagnetic pulse penetrating through the antenna-feeder system. The application of corresponding mathematical models and equations describing the dynamics of transition to chaotic states is considered. The analysis of fractal binary sequences revealed statistical patterns that correlate with the characteristics of complex natural and artificial systems. This opens up prospects for applying methods of generalized statistical thermodynamics in the study of complex information processes, which may be useful for a comprehensive understanding of their structure and dynamics. The obtained results support the hypothesis of a hierarchical organization of such sequences and their invariant nature.

Keywords

Symbolic Dynamics, Chaotic State, Attractor, Fractalized Signal, Thermodynamic, Attractor, Python.

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