Simulation model of the information-measuring system of electrical characteristics of functional coatings of electronic devices
Abstract
The article has developed and researched a simulation model (based on the MatLab Simulink mathematical processor) of the information-measuring system of electrical characteristics (residual surface electric charge, surface layer capacitance, etc.) of functional coatings of electronic devices. The main goal of this simulation model is to determine the rational parameters of measurement and control of the information-measuring system developed by the authors, which would simplify the process of setting up such a system, as well as to study the dynamic modes of its operation. The main advantage of the developed simulation model is the possibility of conducting an interactive study of the operation of the information-measuring system in various, including marginal, regimes. Testing of the simulation model of the information-measuring system makes it possible to investigate its operation under various conditions and regimes of the measurement experiment, as well as to virtually determine the rational parameters of the operation of such a measurement and control system. A satisfactory discrepancy of experimental results of 8-11.5% is established in comparison with the data obtained analytically, which confirms the correctness and adequacy of the developed model. The practical value of the conducted research lies in the possibility of designing high-precision informationmeasuring systems, that take into account the results of simulation modeling, thus ensuring high accuracy (the relative error of determining the residual surface electric charge does not exceed 8-8.5%, and the capacitance of the surface layer does not exceed 4.5%) and repeatability (about 0.998) of the results of the conducted research. In the future, it is planned to carry out hardware implementation and research of the information-measuring system of functional coatings of electronic devices, which will be created taking into account the data obtained from the simulation model about the modes of determining electrical characteristics
Keywords
electronic device; functional coating; information-measuring system; electrical characteristic; simulation model
References
[1] Ajit D. Kelkar, Daniel J. C. Herr, and James G. Ryan, Nanoscience and Nanoengineering: Advances and Applications. Prague, Czech Republic: CRC Press, 2014.
[2] Status of the MEMS industry 2018. Lyon, France: Yole Development SARL, May 2018.
[3] V. Tsenev, "An addition of functionalities in an integrated robot complex for assembling electronic products". Innovations in discrete productions, no. 1, pp. 34-35, 2016. [Online]. Available: https://stumejournals.com/ journals/innovations/2016/1/34.full.pdf
[4] Yong Zhu, Micro and Nano Machined Electrometers. Singapore: Springer, 2020. doi: 10.1007/978-981-13-3247-0.
[5] J. Vedral, and M. Kriz, "Signal processing in partial discharge measurement", Metrology and Measurement Systems, no. 1 (17), pp. 55-63, 2010. [Online]. Available: https://doi.org/10.2478/v10178-010-006-8
[6] C. L.Wadhwa, High Voltage Engineering. New Delhi, India: New Age International, 2007.
[7] A. Sabat, and S. Karmakar, "Simulation of partial discharge in high voltage power equipment", International Journal on Electrical Engineering and Informatics, no. 3 (2), pp. 234-247, 2011.
[8] E. Kuffel, W. S. Zaengl, and J. Kuffel, High Voltage Engineering. London, GB: TBS, 2000.
[9] A. Tzinevrakis, D. Tsanakas, and E. Mimos, "Analytical calculation of the electric field produced by single circuit power lines with horizontal arrangement of the conductors", in 51st Internationales Wissenschaftliches Kolloquium, Technische Universität Ilmenau, Ilmenau, Sept. 11-15, 2006.
[10] Yu. Shi, G. Xie, Q. Wanga X. Li, X. Yang, P. Liu, and Z. Peng, "Simulation analysis and calculation of electric field distribution characteristics of UHV wall bushing", in 4th International Conference on Electrical Engineering and Green Energy CEEGE, Munich, June 10-13, 2021, pp. 110-117. [Online]. Available: https://doi.org/10.1016/ j.egyr.2021.08.066
[11] J. Junior, R. Marcos, C. Tenorio, A. Mateus, and C. Egoavil, "Development of a matlab software for real-time mapping of electric fields on transmission power line", International Journal of Technology, no. 2, pp. 164‐170, 2011.
[12] J. Nalepa, "Modelling and simulation of measuring systems using the Simulink specialised Toolbox", in IX International Syposium on Electrical Instruments in Industry, Glasgow, 1997, pp. 249-252.
[13] D. V. Tychkov, M. O. Bondarenko, and V. S. Antoniuk, "Peculiarities of calculation and research of capacitive dielectric permeability converters with different electrode shapes", Perspektyvni tekhnolohii ta prylady, vol. 14, pp. 140-145, 2019 [in Ukrainian].
[14] M. A. Bondarenko, S. A. Bilokon, V. S. Antonyuk, and Iu. Iu. Bondarenko, "Mechanism of origin and neutralization of residual triboelectricity at scanning of dielectric surfaces by a silicon probe of the atomicforce microscope", Journal of Nano- and Electronic Physics, no. 2 (6), pp. 02018-102018-5, 2014.
[15] D. K. Chaturvedi, Modeling and Simulation of Systems Using MATLAB and Simulink. Boca Raton, USA: CRC Press, 2017. [Online]. Available: https://doi.org/10.1201/ 9781315218335