This work presents a model of the temperature dependence of the vibrational redistribution of energy with its own electromagnetic radiation in electronic circuits on MOS transistors. The work was carried out in a new area of technical diagnostics - radiosensory technical diagnostics and authentication, based on the registration of the electrical component of the near field of electro-magnetic radiation induced by the electronic unit itself. In the ISIS circuit simulation program of the Proteus 8 Professional package, using PSpice component models, a key element model is built, based on the methods of nodal potentials, loop currents and the solution of quadratic equations. The calculated parameters of the model were used to obtain numerical signal radio profiles of the electrical component of electromagnetic radiation and their temperature depend-ences. The relationship between the decay time of oscillations and temperature is shown in the form of a simple analytical expression. An experiment was prepared and carried out to deter-mine the temperature of the key node using the presented model. A correlation assessment of the reproducibility of signal radio profiles obtained as a result of modeling and during the exper-iment was carried out. It was found that their mutual correlation is not lower than 0.93, and the error in determining the decay time is not more than 10%, which indicates the correctness of the presented study. A conclusion is made and the possibility of using the results obtained in radio-sensor technical diagnostics is shown when determining the temperature of an electronic unit or for leveling the temperature drift of the signal radio profile.
1. Yeremenko V.T. Technical diagnostics of electronic devices. Orel: FGBOU VPO «Gosuniversitet – UNPK»; 2012. 157 p. (In Russ)
2. Boikov K.A., Kostin M.S., Kulikov G.V. Radiosensor diagnostics of the integrity of sig-nals of in-circuit and peripheral architecture of microprocessor devices. Rossiyskiy tekhnologicheskiy zhurnal. 2021;9(4):20–27. DOI https://doi.org/10.32362/2500-316X-2021-9-4-20-27. (In Russ)
3. Boikov K.A., Kostin M.S. Method of radiosensor technical diagnostics of microprocessor devices. Novyye tekhnologii vysshey shkoly. Nauka, tekhnika, pedagogika: materialy Vse-rossiyskoy nauchno-prakticheskoy konferentsii «Nauka – Obshchestvo – Tekhnologii – 2021» - Moskva: Moskovskiy Politekh. 2021:119–123. (In Russ)
4. Boikov K.A. Modeling and analysis of vibrational redistribution of energy with its own electromagnetic radiation in key electronic circuits on MOS transistors. Zhurnal radioel-ektroniki [elektronnyy zhurnal]. 2021:6. DOI https://doi.org/10.30898/1684-1719.2021.6.14. (In Russ)
5. Boikov K.A. Method of radio wave authentication of microprocessor devices: pat. 2755153 Ros. Federatsii MPK H04L 9/32 / zayavitel' i pravoobladatel' Boikov K.A. № 2021103796; zayavl. 16.02.2021; opubl. 13.09.2021, Byul. № 26. (In Russ)
6. Kizimenko V.V., Ulanouski A.V. Comparative analysis of the various resonator models in the input impedance calculation of the microstrip antennas. Proceedings of 39-th Interna-tional Conference «Telecommunications and Signal Processing (TSP)». Vienna. June 27-29. 2016.
7. Amelin S.A., Amelina M.A. Varieties of SPICE IGBT Transistors. Proceedings of the VII Int. scientific and technical conference «Energy, Informatics, Innovation». 2017. V 3-kh tomakh. 2017;2:15–20. (In Russ)
8. Basharin S.A. Theoretical Foundations of Electrical Engineering. M.: Akademiya; 2018. 192 p. (In Russ)
9. Yevstifeyev A.V. AVR microcontrollers of the Mega families. User guide. M.: DMK; 2015. 588 p.
10. Ochkurenko G.O. Programming microcontrollers of the AtMega family based on the Ar-duino system. Teoriya i praktika sovremennoy nauki. 2019;4(46):178–183.
11. Boikov K.A. Development and research of a radio pulse regeneration system for high-speed stroboscopic digitizing devices. Zhurnal radioelektroniki [elektronnyy zhurnal]. 2018;3. Available from: http://jre.cplire.ru/jre/mar18/6/text.pdf/.
Boikov Konstantin
Cand. Sci. (Engineering)
MIREA - Russian Technological University
Moscow, Russian Federation
