[1. Barachi, M., Kara, N., Rabah, S., & Forgues, M. (2015). An Open Virtual Multi-Services Networking Architecture for the Future Internet. Journal of Internet Services and Applications, 6(3), 1–22.10.1186/s13174-015-0019-3]Search in Google Scholar
[2. Mykhalevskiy, D. (2017). Development of a Spartial Method for the Estimation of Signal Strength at the Input of the 802.11 Standard Receiver. Easten-European Journal of Enterprise Technologies, 4/9(88), 29–36.10.15587/1729-4061.2017.106925]Search in Google Scholar
[3. Mussabayev, R.R., Kalimoldayev, M.N., Amirgaliyev, Y.N., Tairova, A.T., & Mussabayev, T.R. (2018). Calculation of 3D Coordinates of a Point on the Basis of a Stereoscopic System. Open Engineering, 8(1), 109–117.10.1515/eng-2018-0016]Search in Google Scholar
[4. Nesterenko, S.A., & Ivanova, L.V. (2011). An Analytical Model of the Pass-Through Channel of the Wireless IEEE 802.11 Network Segment. Works of Odessa Polytechnic University, 01(35), 146–150.]Search in Google Scholar
[5. Nesterenko, S.A., & Nesterenko, Yu.S. (2015). Analysis of the Bandwidth of the Wireless Channel in the Accelerated Transmission Modes. East European Magazine of Advanced Technology, 3/9(75), 20–24.]Search in Google Scholar
[6. Kim, H., Park, E.C., Lee, S.K., & Hu, C. (2011). Fast Performance Assessment of IEEE 802.11-based Wireless Networks. Mathematical and Computer Modelling, 53, 2173–2191.10.1016/j.mcm.2010.08.024]Search in Google Scholar
[7. Yarilovets, A.V., Nazaruk, V.D., & Zaitsev, S.V. (2014). An Evaluation of the Efficiency of Information Technology for Wireless Access Systems Built on the Basis of Optimal Orthogonal Multi-Frequency Signal Constructions. Mathematical Machines and Systems, 2, 51–58.]Search in Google Scholar
[8. Amirgaliyev, B.Y., Kenshimov, C.A., Baibatyr, Z.Y., Kuatov, K.K., Kairanbay, M.Z., & Jantassov, A.K. (2015). Statistical Inference in ALPR System. In 9th International Conference on Application of Information and Communication Technologies, AICT 2015 – Proceedings (pp. 310–313), 25 November 2015, Article number 7338569.10.1109/ICAICT.2015.7338569]Search in Google Scholar
[9. Kychak, V.M., & Tromsyuk, V.D. (2017). Assessment Method of Parameters and Characteristics of Bit Errors. Journal of Automation and Information Sciences, 49(5), 59–71.10.1615/JAutomatInfScien.v49.i5.50]Open DOISearch in Google Scholar
[10. Sharma, R., Singh, G., & Agnihotri, R. (2010). Comparison of Performance Analysis of 802.11a, 802.11b and 802.11g Standard. International Journal on Computer Science and Engineering, 02(06), 2042–2046.]Search in Google Scholar
[11. Mykhalevskiy, D., Vasylkivskiy, N., & Horodetska, O. (2017). Development of a Mathematical Model for Estimating Signal Strength at the Input of the 802.11 Standard Receiver. Easten-European Journal of Enterprise Technologies, 4/9(88), 38–43.10.15587/1729-4061.2017.114191]Search in Google Scholar
[12. Gorbaty, I.V. (2017). Research of Technical Efficiency of Telecommunication Systems and Networks Using Different Methods of Data Transmission with Feedback Manager. Information and Control Systems on the Railway Transport, 1, 18–23.]Search in Google Scholar
[13. Prokis, D. (2000). Digital communication. Moscow: Radio i svyaz’.]Search in Google Scholar
[14. Insam E. (2003). TCP/IP embedded internet applications. Oxford: Elsevier Ltd.]Search in Google Scholar
[15. Perahia, E., & Stacey, R. (2013). Next generation wireless LANs: 802.11n and 802.11ac. Cambridge: Cambridge University Press.10.1017/CBO9781139061407]Search in Google Scholar
[16. Buyankin, V.M. (2018). Neuroidentification With Neuro-Self Tuning to Ensure the Operation of the Current Loop of the Electric Drive with the Desired Static and Dynamic Characteristics. Periodico Tche Quimica, 15(30), 513–520.10.52571/PTQ.v15.n30.2018.517_Periodico30_pgs_513_519.pdf]Search in Google Scholar
[17. Mykhalevskiy, D.V. (2018). Construction of Mathematical Models for the Estimation of Signal Strength at the Input to the 802.11 Standard Receiver in a 5 GHz Band. Easten-European Journal of Enterprise Technologies, 6/9(96), 16–21.10.15587/1729-4061.2018.150983]Search in Google Scholar
[18. Mykhalevskiy, D.V. (2019). Investigation of Wireless Channels of 802.11 Standard in the 5GHz Frequency Band. Latvian Journal of Physics and Technical Sciences, 1, 41–51.10.2478/lpts-2019-0004]Search in Google Scholar
[19. Mykhalevskiy, D.V., & Horodetska, O.S. (2019). Investigation of Wireless Channels according to the Standard 802.11 in the Frequency Range of 5 GHz for Two Subscribers. Journal of Mechanical Engineering Research & Developments, 42(2), 50–57.10.26480/jmerd.02.2019.50.57]Search in Google Scholar