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OPTIMAL SWITCHING LOSS REDUCTION IN THREE-PHASE VSI USING THRESHOLDED RIDER OPTIMIZATION ALGORITHM
G. Rajeshkumar and P. Sujatha Therese
References
[1] W. Chen, H. Sun, X. Gu, and C. Xia, Synchronized space-vector PWM for three-level VSI with lower harmonic distortion and switching frequency, IEEE Transactions on Power Electronics, 31(9), 2016, 6428–6441.
[2] O. Oñederra, I. Kortabarria, I.M. de Alegr´ıa, J. Andreu, and J.I. Gárate, Three-phase VSI optimal switching loss reduction using variable switching frequency, IEEE Transactions on Power Electronics, 32(8), 2017, 6570–6576.
[3] F. Mwasilu, E. Kim, M.S. Rafaq, and J. Jung, Finite-set model predictive control scheme with an optimal switching voltage vector technique for high-performance IPMSM drive applications, IEEE Transactions on Industrial Informatics, 14(9), 2018, 3840–3848.
[4] T.N. Nguyen, A. Luo, and M. Li, A simple and robust method for designing a multi-loop controller for three-phase VSI with an LCL-filter under uncertain system parameters, Electric Power Systems Research, 117, 2014, 94–103.
[5] M. Trabelsi, M. Boussak, and M. Benbouzid, Multiple criteria for high-performance real-time diagnostic of single and multiple open-switch faults in ac-motor drives: Application to IGBTbased voltage source inverter, Electric Power Systems Research, 144, 2017, 136–149.
[6] S.Wang, C. Li, C. Che, and D. Xu, Direct torque control for 2LVSI PMSM using switching instant table, IEEE Transactions on Industrial Electronics, 65(12), 2018, 9410–9420.
[7] K. Chen and Y. Xie, Reducing harmonics distortion in fivephase VSI using space-vector-based optimal hybrid PWM, IEEE Transactions on Power Electronics, 32(3), 2017, 2098– 2113.
[8] R.B. Dhumale and S.D. Lokhande, Neural network fault diagnosis of voltage source inverter under variable load conditions at different frequencies, Measurement, 91, 2016, 565–575.
[9] K. Thakre, K.B. Mohanty, and A. Chatterjee, Reduction of circuit devices in symmetrical voltage source multilevel inverter based on the series connection of basic unit cells, Alexandria Engineering Journal, 15 November 2018.
[10] I. Ziouani, D. Boukhetala, A.-M. Darcherif, B. Amghar, and I. El Abbassi, Hierarchical control for flexible microgrid based on three-phase voltage source inverters operated in parallel, International Journal of Electrical Power & Energy Systems, 95, 2018, 188–201.
[11] S. Dowruang, P. Bumrungsri, and C. Jeraputra, Improved voltage vector sequences on model predictive control for a grid connected three phase voltage source inverter, Procedia Computer Science, 86, 2016, 393–396.
[12] N. Raj, J. Mathew, G. Jagadanand, and S. George, Opentransistor fault detection and diagnosis based on current trajectory in a two-level voltage source inverter, Procedia Technology, 25, 2016, 669–675.
[13] A. Shokri, H. Shareef, A. Mohamed, M. Farhoodnea, and H. Zayandehroodi, A novel controller for a voltage controlled voltage source inverter to mitigation voltage fluctuations measured at the point of common coupling, Measurement, 59, 2015, 216–226.
[14] O. Duque-Perez, L.-A. Garcia-Escudero, D. Morinigo-Sotelo, P.-E. Gardel, and M. Perez-Alonso, Analysis of fault signatures for the diagnosis of induction motors fed by voltage source inverters using ANOVA and additive models, Electric Power Systems Research, 121, 2015, 1–13.
[15] S.B. Naderi, M. Negnevitsky, A. Jalilian, M.T. Hagh, Efficient fault ride-through scheme for three phase voltage source inverter-interfaced distributed generation using DC link adjustable resistive type fault current limiter, Renewable Energy, 92, 2016, 484–498.
[16] T. Abdelkrim, T. Benslimane, A. Borni, K. Benamrane, and N. Bouarroudj, Performance evaluation of a new control scheme of distributed two-stage PV conversion system using three levels voltage source inverter for stand-alone application, Energy Procedia, 119, 2017, 270–277.
[17] A.A.A. Radwan, Y.A.-R.I. Mohamed, and E.F. El-Saadany, Assessment and performance evaluation of DC-side interactions of voltage-source inverters interfacing renewable energy systems, Sustainable Energy, Grids and Networks, 1, 2015, 28–44.
[18] F. Mehazzem, A.L. Nemmour, and A. Reama, Real time implementation of backstepping-multiscalar control to induction motor fed by voltage source inverter, International Journal of Hydrogen Energy, 42(28), 2017, 17965–17975.
[19] M. Fateh and R. Abdellatif, Comparative study of integral and classical backstepping controllers in IFOC of induction motor fed by voltage source inverter, International Journal of Hydrogen Energy, 42(28), 2017, 17953–17964.
[20] P.-E. Vidal, S. Cailhol, and F. Rotella, Generic modeling of N-level pulse width modulation voltage source inverters and their control”, IFAC-PapersOnLine, 50(1), 2017, 7813–7818.
[21] J. Linares-Flores, J.F. Guerrero-Castellanos, R. LescasHernndez, A. Hernndez-Mndez, and R. Vzquez-Perales, Angular speed control of an induction motor via a solar powered boost converter-voltage source inverter combination, Energy, 166, 2019, 326–334.
[22] S.M. Muyeen, A. Al-Durra, and J. Tamura, Variable speed wind turbine generator system with current controlled voltage source inverter, Energy Conversion and Management, 52(7), 2011, 2688–2694.
[23] S.Y.M. Mousavi, A. Jalilian, M. Savaghebi, and J.M. Guerrero, Coordinated control of multifunctional inverters for voltage support and harmonic compensation in a grid-connected microgrid, Electric Power Systems Research, 155, 2018, 254–264.
[24] A. Darwish, A.S. Abdel-Khalik, A. Elserougi, S. Ahmed, and A. Massoud, Fault current contribution scenarios for gridconnected voltage source inverter-based distributed generation with an LCL filter, Electric Power Systems Research, 104, 2013, 93–103.
[25] D. Binu and B.S. Kariyappa, RideNN: A new rider optimization algorithm-based neural network for fault diagnosis in analog circuits, IEEE Transactions on Instrumentation and Measurement, 68(1), 2019, 2–26.
[26] J. McCall, Genetic algorithms for modelling and optimisation, Journal of Computational and Applied Mathematics, 184(1), 2005, 205–222.
[27] J. Zhang and P. Xia, An improved PSO algorithm for parameter identification of nonlinear dynamic hysteretic models, Journal of Sound and Vibration, 389, 2017, 153–167.
[28] I. Fister, I. Fister, X.-S. Yang, and J. Brest, A comprehensive review of firefly algorithms, Swarm and Evolutionary Computation, 13, 2013, 34–46.
[29] S. Mirjalili, S.M. Mirjalili, and A. Lewis, Grey wolf optimizer, Advances in Engineering Software, 69, 2014, 46–61.
[30] D. Jiang and F. Wang, A general current ripple prediction method for the multiphase voltage source converter, IEEE Transactions on Power Electronics, 29(6), 2014, 2643–2648.
[31] G. Grandi, J. Loncarski, and O. Dordevic, Analytical evaluation of output current ripple amplitude in three-phase three-level inverters, IET Power Electronics, 7(9), 2014, 2258–2268.
[32] A. Ibrahim and M.Z. Sujod, Variable switching frequency hybrid PWM technique for switching loss reduction in a threephase two-level voltage source inverter, Measurement, 151, 2020, 107192.
[33] I.H. Shanono, N.R.H. Abdullah, H. Daniyal, and A. Muhammad, Selective harmonic elimination (SHE) based 3-phase multilevel voltage source inverter (VSI) for standalone applications, SN Applied Sciences, 1(12), 2019, 1670.
[34] O. Oñederra, I. Kortabarria, I.M. de Alegr´ıa, J. Andreu, and J.I. Gárate, Three-phase VSI optimal switching loss reduction using variable switching frequency, IEEE Transactions on Power Electronics, 32(8), 2016, 6570–6576.
[35] G. Nalcaci and M. Ermis, Selective harmonic elimination for three-phase voltage source inverters using whale optimizer algorithm, in: 2018 5th International Conference on Electrical and Electronic Engineering (ICEEE) (IEEE, 2018), 1–6.
[36] A. Anuchin, D. Aliamkin, M. Lashkevich, D. Shpak, A. Zharkov, and F. Briz, Minimization and redistribution of switching losses using predictive PWM strategy in a voltage source inverter, in 2018 25th International Workshop on Electric Drives: Optimization in Control of Electric Drives (IWED) (IEEE, 2018), 1–6.
[37] A. Abdelhakim, P. Davari, F. Blaabjerg, and P. Mattavelli, Switching loss reduction in the three-phase quasi-Z-source inverters utilizing modified space vector modulation strategies, IEEE Transactions on Power Electronics, 33(5), 2017, 4045– 4060.
[38] I. Ziouani, D. Boukhetala, A.M. Darcherif, B. Amghar, and I. El Abbassi, Hierarchical control for flexible microgrid based on three-phase voltage source inverters operated in parallel, International Journal of Electrical Power & Energy Systems, 95, 2018, 188–201.
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Abstract
DOI:
10.2316/J.2021.203-0191
From Journal
(203) International Journal of Power and Energy Systems - 2021
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