Mathematical, algorithmic and software support for signals wavelet detection in electronic communications

Khvostivska, Liliia; Khvostivskyi, Mykola; Dediv, Iryna

Будь ласка, використовуйте цей ідентифікатор, щоб цитувати або посилатися на цей матеріал: http://elartu.tntu.edu.ua/handle/lib/46337

Повний запис метаданих

Поле DC	Значення	Мова
dc.contributor.author	Khvostivska, Liliia	-
dc.contributor.author	Khvostivskyi, Mykola	-
dc.contributor.author	Dediv, Iryna	-
dc.date.accessioned	2024-09-10T17:01:12Z	-
dc.date.available	2024-09-10T17:01:12Z	-
dc.date.issued	2024-06-14	-
dc.identifier.citation	Khvostivska L., Khvostivskyi M., Dediv I. Mathematical, algorithmic and software support for signals wavelet detection in electronic communications. Proceedings of the 2nd International Workshop on Computer Information Technologies in Industry 4.0 (CITI 2024). CEUR Workshop Proceedings. Ternopil, Ukraine, June 14-16, 2024. Vol. 3742. P.223-234. ISSN 1613-0073.	uk_UA
dc.identifier.issn	1613-0073	-
dc.identifier.uri	http://elartu.tntu.edu.ua/handle/lib/46337	-
dc.description.abstract	In the work based on wavelet processing of signals in the Mexican HAT mother base, a mathematical (method) and algorithmic support for wavelet detection of useful signals in electronic communications against the background of noises was developed. 3D and 2D (averaged 3D) wavelet spectra, taking into account scale and shift indicators, are used as wavelet features for signal detection. Wavelet software for detecting useful signals in electronic communications has been developed in the Matlab environment. It is established that the developed software provides reliable wavelet detection of signals in electronic communications by wavelet spectra with the Mexican HAT basis function, which quantitatively and visually reflect the presence/absence of useful signals in electronic communications with noises.	uk_UA
dc.format.extent	223-234	-
dc.language.iso	en	uk_UA
dc.publisher	CEUR Workshop Proceedings	uk_UA
dc.relation.uri	https://ceur-ws.org/Vol-3742/paper16.pdf	uk_UA
dc.subject	signal	uk_UA
dc.subject	electronic communication	uk_UA
dc.subject	mathematical and algorithmic support	uk_UA
dc.subject	wavelet detection	uk_UA
dc.subject	software	uk_UA
dc.title	Mathematical, algorithmic and software support for signals wavelet detection in electronic communications	uk_UA
dc.type	Article	uk_UA
dc.coverage.placename	CEUR Workshop Proceedings. Ternopil, Ukraine	uk_UA
dc.relation.references	Melvin W L and Scheer J A 2013 Principles of Modern Radar: Advanced Techniques (New York:SciTech Publishing, IET, Edison). P. 846.	uk_UA
dc.relation.references	Richards M A, Scheer J A and Holm W A 2010 Principles of Modern Radar: Basic Principles (New York: SciTech Publishing, IET, Edison). P. 924.	uk_UA
dc.relation.references	Kolumbán G., Krébesz T. Chaotic Communications with Autocorrelation Receiver: Modeling, Theory and Performance Limits. Intelligent Computing Based on Chaos, 2009, SCI 184, pp. 121–143. doi: 10.1007/978-3-540-95972-4_6.	uk_UA
dc.relation.references	Laptiev O., Polovinkin I., Vitalii S., Stefurak O., Barabash O. and Zelikovska O. The Method of Improving the Signal Detection Quality by Accounting for Interference. 2020 IEEE 2nd International Conference on Advanced Trends in Information Theory (ATIT), 2020, pp. 172-175. doi: 10.1109/ATIT50783.2020.9349259.	uk_UA
dc.relation.references	Yu.É. Korchagin, K.D. Titov Detection of an Ultra-Wideband Quasi Radio Signal with Unknown Duration Against the Background of White Noise. Radiophysics and Quantum Electronics volume 61, pp.853–866 (2019). DOI: 10.1007/s11141-019-09942-5.	uk_UA
dc.relation.references	Trifonov A.P., Korchagin Yu.É., Trifonov M.V.. Detection of Radio Signals with Unknown Duration, Amplitude, and Initial Phase. Radiophysics and Quantum Electronics, Volume 58, Issue 5, pp.361-372. October 2015. doi: 10.1007/s11141-015-9610-5.	uk_UA
dc.relation.references	Xue Y, Li X, Xu L and Ren Y 2012 Research on position differential method of dualsatellitesTDOA and FDOA in passivelocation system. IEEE International Frequency Control Symposiumpp 1–5.	uk_UA
dc.relation.references	Proakis J G and Manolakis D G 2007 Digital Signal Processing: Principles, Algorithms andApplications (New Jersey: Pearson Prentice Hall) p. 1084.	uk_UA
dc.relation.references	Wu R, Zhang Y, Huang Y, Xiong J and Deng Z 2018 A Novel Long-Time Accumulation Methodfor Double-Satellite TDOA/FDOA Interference Localization. Radio Science 53 129–142.	uk_UA
dc.relation.references	Tsymbaliuk, I., & Horbatyi, I. (2023). Approach to processing radio signals with amplitude modulation of many components using one-dimensional convolutional neural network. Eastern-European Journal of Enterprise Technologies, 6(9 (126), 14– 22. https://doi.org/10.15587/1729-4061.2023.292854.	uk_UA
dc.relation.references	Myasnikov, E.N., Zaboronkova, T.M., & Kogan, L.P. (2021). ZaboronkovaL Kogan. Detection of radio signals against the background of strongelectromagnetic noise in transport. Journal of Physics: Conference Series Journal of Physics Conference Series. 2131(5):052046. DOI: 10.1088/1742-6596/2131/5/052046.	uk_UA
dc.relation.references	Khvostivska L.V., Koval L.M. Detection of useful radio signals as periodically correlated stochastic processes under conditions of a priori uncertainty. Materials of the 4th AllUkrainian scientific and practical Internet conference of students, postgraduates and young scientists on the topic "Modern computer systems and networks in management": a collection of scientific works / Edited by G.O. Rayko. Kherson: Publishing House FOP Vyshemirskyi V.S., 2021. P.133.	uk_UA
dc.relation.references	Khvostivska L., Khvostivskyy M., Dunetc V., Dediv I. Mathematical and Algorithmic Support of Detection Useful Radiosignals in Telecommunication Networks. Proceedings of the 2nd International Workshop on Information Technologies: Theoretical and Applied Problems (ITTAP 2022). Ternopil, Ukraine, November 22-24, 2022. P.314-318. ISSN 1613-0073.	uk_UA
dc.relation.references	Khvostivska L., Khvostivskyi M., Dunets V., Dediv I. (2023) Mathematical, algorithmic and software support of synphase detection of radio signals in electronic communication networks with noises. Scientific Journal of TNTU (Tern.), vol 111, no 3, pp. 48–57. ISSN 2522-4433.	uk_UA
dc.relation.references	Khvostivska L., Khvostivskyi M., Dediv I., Yatskiv V., Palaniza Y. Method, Algorithm and Computer Tool for Synphase Detection of Radio Signals in Telecommunication Networks with Noises. Proceedings of the 1st International Workshop on Computer Information Technologies in Industry 4.0 (CITI 2023). CEUR Workshop Proceedings. Ternopil, Ukraine, June 14-16, 2023. P.173-180. ISSN 1613-0073.	uk_UA
dc.relation.references	Khvostivska L.V., Kazmiriv V.V., Remez A.V. (2022) Wavelet processing of radiosignals for the problem of their detection against the background of interferences [Вейвлет обробка радіосигналів для задачі їх виявлення на фоні завад]. ⅩⅠ International scientific and practical conference of young researchers and students «Current issues in modern technologies» (Tern., 7-8 December 2022), pp. 119-120. [in Ukrainian].	uk_UA
dc.relation.references	Ali N. Akansu, Richard A. Haddad. Chapter 6 - Wavelet Transform. Editor(s): Ali N. Akansu, Richard A. Haddad. Multiresolution Signal Decomposition (Second Edition). Academic Press, 2001. Pages 391-442. ISBN 9780120471416. https://doi.org/10.1016/B978-012047141-6/50006-9.	uk_UA
dc.relation.references	Singh, A., Rawat, A., Raghuthaman, N. (2022). Mexican Hat Wavelet Transform and Its Applications. In: Singh, J., Dutta, H., Kumar, D., Baleanu, D., Hristov, J. (eds) Methods of Mathematical Modelling and Computation for Complex Systems. Studies in Systems, Decision and Control, vol 373. Springer, Cham. https://doi.org/10.1007/978-3-030- 77169-0_12.	uk_UA
dc.relation.references	Mohammed A. Abdala. Genetically Based Wavenets for System Modeling. (2008). Journal of Engineering and Sustainable Development, 12(3), 120-132. https://jeasd.uomustansiriyah.edu.iq/index.php/jeasd/article/view/1685.	uk_UA
dc.relation.references	Yan, Y., Zhou, M., Zhang, D. et al. Scale-invariant Mexican Hat wavelet descriptor for non-rigid shape similarity measurement. Sci Rep 13, 2518 (2023). https://doi.org/10.1038/s41598-023-29047-4.	uk_UA
dc.relation.references	Martsenyuk, V., Sverstiuk, A., Klos-Witkowska, Kozodii, N., Bagriy-Zayats, O., Zubenko, I. Numerical analysis of results simulation of cyber-physical biosensor systems. CEUR Workshop Proceedings, 2019, 2516, pp. 149–164.	uk_UA
dc.relation.references	Martsenyuk, V., Klos-Witkowska, A., Sverstiuk, A. Stability Investigation of Biosensor Model Based on Finite Lattice Difference Equations. Springer Proceedings in Mathematics and Statistics, 2020, 312, pp. 297–321. https://doi.org/10.1007/978-3- 030-35502-9_13.	uk_UA
dc.coverage.country	UA	uk_UA
Розташовується у зібраннях:	Наукові публікації працівників кафедри біотехнічних систем

Файли цього матеріалу:

Файл	Опис	Розмір	Формат
Mathematical, algorithmic and software support for signals wavelet detection in electronic communications.pdf	Khvostivska L., Khvostivskyi M., Dediv I. Mathematical, algorithmic and software support for signals wavelet detection in electronic communications. Proceedings of the 2nd International Workshop on Computer Information Technologies in Industry 4.0 (CITI 2024). CEUR Workshop Proceedings. Ternopil, Ukraine, June 14-16, 2024. Vol. 3742. P.223-234. ISSN 1613-0073.	1,86 MB	Adobe PDF	Переглянути/відкрити

Показати базовий опис матеріалу Перегляд статистики

Усі матеріали в архіві електронних ресурсів захищені авторським правом, всі права збережені.

Інструменти адміністратора