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MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter

Year 2024, , 701 - 716, 01.06.2024
https://doi.org/10.35378/gujs.1342626

Abstract

Power electronic systems are rapidly evolving; thus, effective prototyping methods are required to test control algorithms and assess system performance prior to hardware implementation. This research suggests a Model-In-The-Loop (MIL), Software-In-The-Loop (SIL), and Processor-In-The-Loop (PIL) methodologies-based complete prototyping strategy for flyback converters using the TI F28069M Launchpad kit. These techniques can be combined to evaluate control strategies accurately and quickly, speeding up design cycles and enhancing system reliability. The proposed prototyping platform is presented in this work, along with a thorough explanation of each prototyping stage and its associated advantages. The effectiveness of the suggested approach for 50W rated power flyback converter in terms of quick algorithm development, system simulation, real-time control implementation and controller design accuracy is analyzed and shown by experimental results. The results show that the performance of the designed controller for the flyback converter is almost the same as in MIL and SIL implementation in terms of the overshoot and settling time in the reference voltage tracking. On the other hand, in the PIL implementation, the overshoot performance of the controller deviates by 1.18% more than in SIL and MIL implementation. These also confirm that the flyback control system's performance is reliable and effective during all phases of development.

References

  • [1] Bose, B.K., Power electronics in renewable energy systems and smart grid: technology and applications 1st ed., New Jersey, (2019).
  • [2] Jahns, T.M., and Blasko, V., "Recent advances in power electronics technology for industrial and traction machine drives", Proceedings of the IEEE, 89(6): 963-975, (2001).
  • [3] Abu-Rub, H., Malinowski, M., and Al-Haddad, K., Power electronics for renewable energy systems, transportation and industrial applications 1st ed., West Sussex, (2014).
  • [4] Venkatesan, K., "Current mode controlled bidirectional flyback converter", 20th Annual IEEE Power Electronics Specialists Conference, Milwaukee, 835-842, (1989).
  • [5] Liang, T.J., Chen, K.H., and Chen, J.F., "Primary side control for flyback converter operating in DCM and CCM", IEEE Transactions on Power Electronics, 33(4): 3604-3612, (2017).
  • [6] Mohammed, A.A., and Nafie, S.M., "Flyback converter design for low power application", International conference on computing, control, networking, electronics and embedded systems engineering (ICCNEEE), Khartoum, 447-450, (2015).
  • [7] Bunyamin, T., and Kirimer, B., "An interleaved high-power flyback inverter for photovoltaic applications", IEEE transactions on Power Electronics, 30(6): 3228-3241, (2014).
  • [8] Ponce-Silva, M., Salazar-Perez, D., Rodriguez, O.M., Vela-Valdes, L.G., Claudio-Sanchez, A., De Leon-Aldaco, S.E., Cortes-Garcia, C., Saavedra-Benitez, Y.I., Lozoya-Ponce, R.E., and Aqui-Tapia, J.A., "Flyback converter for solid-state lighting applications with partial energy processing", Electronics, 10(1): 60, (2020).
  • [9] Ma, W., Chen, Y., and Yao, D., “PC-based real-time simulator and its application on testing of power plant auxiliary system control”, 2010 International Conference on Power System Technology, Hangzhou, 1–4, (2010).
  • [10] Miyazaki, Y., Kimura, M., Karube, T., Noro, Y., Takahashi, C., Kishibe, H., and Sato, H., “Development and verification of a FACTS digital realtime simulator”, IEEE/PES Transmission and Distribution Conference and Exhibition, Yokohama, 1: 324–329, (2002).
  • [11] Hercog, D., Curkovic, M., and Jezernik, K., “DSP based rapid control prototyping systems for engineering education and research”, 2006 IEEE Conference on Computer Aided Control System Design, Munich, 2292-2297, (2006).
  • [12] Hao, X., Fu, L., Ma, F., and Li, C., “Real-time simulation hardware-in-the-loop test platform for DC integrated power system containing a large number of switches”, IEEE 5th International Electrical and Energy Conference (CIEEC), Nangjing, 1600–1605, (2022).
  • [13] Ruelland, R., Gateau, G., Meynard, T.A., and Hapiot, J. -C., “Design of FPGA-based emulator for series multicell converters using co-simulation tools”, IEEE Transactions on Power Electronics, 18(1): 455–463, (2003).
  • [14] Dufour, C., Lapointe, V., Bélanger, J., and Abourida, S., “Hardware-in-the-loop closed-loop experiments with an FPGA-based permanent magnet synchronous motor drive system and a rapidly prototyped controller”, 2008 IEEE International Symposium on Industrial Electronics, Cambridge, 2152–2158, (2008).
  • [15] He, L., Wang, F., and Ke, D., “FPGA-based sliding-mode predictive control for PMSM speed regulation system using an adaptive ultralocal model”, IEEE Transactions on Power Electronics, 36(5): 5784–5793, (2021).
  • [16] Zheng, J., Zhao, Z., Zeng, Y., Shi, B., and Yu, Z., “An event-driven real-time simulation for power electronics systems based on discrete hybrid time-step algorithm”, IEEE Transactions on Industrial Electronics, 70(5): 4809–4819, (2023).
  • [17] Rodal, G.L., and Peftitsis, D., “Real-time FPGA simulation of high-voltage silicon carbide MOSFETs”, IEEE Transactions on Power Electronics, 38(3): 3213–3234, (2023).
  • [18] Mao, C., Leng, F., Li, J., Zhang, S., Zhang, L., Mo, R., Wand, D., Zeng, J., Chen, X., An, R., and Zhao, Y., “A 400-V/50-kVA digital–physical hybrid real-time simulation platform for power systems”, IEEE Transactions on Industrial Electronics, 65(5): 3666–3676, (2018).
  • [19] Akbarabadi, S.A., Atighechi, H., and Jatskevich, J., “Circuit-averaged and state-space-averaged-value modeling of second-order flyback converter in CCM and DCM including conduction losses”, 4th International Conference on Power Engineering, Energy and Electrical Drives, İstanbul, 995-1000, (2013).
Year 2024, , 701 - 716, 01.06.2024
https://doi.org/10.35378/gujs.1342626

Abstract

References

  • [1] Bose, B.K., Power electronics in renewable energy systems and smart grid: technology and applications 1st ed., New Jersey, (2019).
  • [2] Jahns, T.M., and Blasko, V., "Recent advances in power electronics technology for industrial and traction machine drives", Proceedings of the IEEE, 89(6): 963-975, (2001).
  • [3] Abu-Rub, H., Malinowski, M., and Al-Haddad, K., Power electronics for renewable energy systems, transportation and industrial applications 1st ed., West Sussex, (2014).
  • [4] Venkatesan, K., "Current mode controlled bidirectional flyback converter", 20th Annual IEEE Power Electronics Specialists Conference, Milwaukee, 835-842, (1989).
  • [5] Liang, T.J., Chen, K.H., and Chen, J.F., "Primary side control for flyback converter operating in DCM and CCM", IEEE Transactions on Power Electronics, 33(4): 3604-3612, (2017).
  • [6] Mohammed, A.A., and Nafie, S.M., "Flyback converter design for low power application", International conference on computing, control, networking, electronics and embedded systems engineering (ICCNEEE), Khartoum, 447-450, (2015).
  • [7] Bunyamin, T., and Kirimer, B., "An interleaved high-power flyback inverter for photovoltaic applications", IEEE transactions on Power Electronics, 30(6): 3228-3241, (2014).
  • [8] Ponce-Silva, M., Salazar-Perez, D., Rodriguez, O.M., Vela-Valdes, L.G., Claudio-Sanchez, A., De Leon-Aldaco, S.E., Cortes-Garcia, C., Saavedra-Benitez, Y.I., Lozoya-Ponce, R.E., and Aqui-Tapia, J.A., "Flyback converter for solid-state lighting applications with partial energy processing", Electronics, 10(1): 60, (2020).
  • [9] Ma, W., Chen, Y., and Yao, D., “PC-based real-time simulator and its application on testing of power plant auxiliary system control”, 2010 International Conference on Power System Technology, Hangzhou, 1–4, (2010).
  • [10] Miyazaki, Y., Kimura, M., Karube, T., Noro, Y., Takahashi, C., Kishibe, H., and Sato, H., “Development and verification of a FACTS digital realtime simulator”, IEEE/PES Transmission and Distribution Conference and Exhibition, Yokohama, 1: 324–329, (2002).
  • [11] Hercog, D., Curkovic, M., and Jezernik, K., “DSP based rapid control prototyping systems for engineering education and research”, 2006 IEEE Conference on Computer Aided Control System Design, Munich, 2292-2297, (2006).
  • [12] Hao, X., Fu, L., Ma, F., and Li, C., “Real-time simulation hardware-in-the-loop test platform for DC integrated power system containing a large number of switches”, IEEE 5th International Electrical and Energy Conference (CIEEC), Nangjing, 1600–1605, (2022).
  • [13] Ruelland, R., Gateau, G., Meynard, T.A., and Hapiot, J. -C., “Design of FPGA-based emulator for series multicell converters using co-simulation tools”, IEEE Transactions on Power Electronics, 18(1): 455–463, (2003).
  • [14] Dufour, C., Lapointe, V., Bélanger, J., and Abourida, S., “Hardware-in-the-loop closed-loop experiments with an FPGA-based permanent magnet synchronous motor drive system and a rapidly prototyped controller”, 2008 IEEE International Symposium on Industrial Electronics, Cambridge, 2152–2158, (2008).
  • [15] He, L., Wang, F., and Ke, D., “FPGA-based sliding-mode predictive control for PMSM speed regulation system using an adaptive ultralocal model”, IEEE Transactions on Power Electronics, 36(5): 5784–5793, (2021).
  • [16] Zheng, J., Zhao, Z., Zeng, Y., Shi, B., and Yu, Z., “An event-driven real-time simulation for power electronics systems based on discrete hybrid time-step algorithm”, IEEE Transactions on Industrial Electronics, 70(5): 4809–4819, (2023).
  • [17] Rodal, G.L., and Peftitsis, D., “Real-time FPGA simulation of high-voltage silicon carbide MOSFETs”, IEEE Transactions on Power Electronics, 38(3): 3213–3234, (2023).
  • [18] Mao, C., Leng, F., Li, J., Zhang, S., Zhang, L., Mo, R., Wand, D., Zeng, J., Chen, X., An, R., and Zhao, Y., “A 400-V/50-kVA digital–physical hybrid real-time simulation platform for power systems”, IEEE Transactions on Industrial Electronics, 65(5): 3666–3676, (2018).
  • [19] Akbarabadi, S.A., Atighechi, H., and Jatskevich, J., “Circuit-averaged and state-space-averaged-value modeling of second-order flyback converter in CCM and DCM including conduction losses”, 4th International Conference on Power Engineering, Energy and Electrical Drives, İstanbul, 995-1000, (2013).
There are 19 citations in total.

Details

Primary Language English
Subjects Circuits and Systems, Electronic Device and System Performance Evaluation, Testing and Simulation, Power Electronics, Control Theoryand Applications
Journal Section Electrical & Electronics Engineering
Authors

Muhammad Alı 0009-0004-8959-3208

İsmet Şen 0009-0002-6690-3440

Salih Barış Öztürk 0000-0001-8322-4066

Emre Avcı 0000-0003-2086-1417

Early Pub Date December 10, 2023
Publication Date June 1, 2024
Published in Issue Year 2024

Cite

APA Alı, M., Şen, İ., Öztürk, S. B., Avcı, E. (2024). MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter. Gazi University Journal of Science, 37(2), 701-716. https://doi.org/10.35378/gujs.1342626
AMA Alı M, Şen İ, Öztürk SB, Avcı E. MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter. Gazi University Journal of Science. June 2024;37(2):701-716. doi:10.35378/gujs.1342626
Chicago Alı, Muhammad, İsmet Şen, Salih Barış Öztürk, and Emre Avcı. “MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter”. Gazi University Journal of Science 37, no. 2 (June 2024): 701-16. https://doi.org/10.35378/gujs.1342626.
EndNote Alı M, Şen İ, Öztürk SB, Avcı E (June 1, 2024) MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter. Gazi University Journal of Science 37 2 701–716.
IEEE M. Alı, İ. Şen, S. B. Öztürk, and E. Avcı, “MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter”, Gazi University Journal of Science, vol. 37, no. 2, pp. 701–716, 2024, doi: 10.35378/gujs.1342626.
ISNAD Alı, Muhammad et al. “MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter”. Gazi University Journal of Science 37/2 (June 2024), 701-716. https://doi.org/10.35378/gujs.1342626.
JAMA Alı M, Şen İ, Öztürk SB, Avcı E. MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter. Gazi University Journal of Science. 2024;37:701–716.
MLA Alı, Muhammad et al. “MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter”. Gazi University Journal of Science, vol. 37, no. 2, 2024, pp. 701-16, doi:10.35378/gujs.1342626.
Vancouver Alı M, Şen İ, Öztürk SB, Avcı E. MIL, SIL and PIL Implementation for Closed Loop Control of Flyback Converter. Gazi University Journal of Science. 2024;37(2):701-16.