ijece-140502292014050229202750CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagNashriyyah -i Muhandisi -i Barq va Muhandisi -i Kampyutar -i Iranijece168237451162023204sogandnikkhahMohammadRezanejadRezakhosravi116202330931610.66224/ijece.29230.20.4.309http://ijece.org/fa/Article/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230http://ijece.org/fa/Article/Download/29230[1] J. R. Beveridge, S. J. MacGregor, J. G. Anderson, and R. A. Fouracre, "The influence of pulse duration on the inactivation of bacteria using monopolar and bipolar profile pulsed electric fields," IEEE Trans. on Plasma Sci., vol. 33, no. 4, pp. 1287-1293, Aug. 2005. [2] M. P. J. Gaudreau, T. Hawkey, J. Petry, and M. Kempkes, "Pulsed power systems for food and wastewater processing," in Proc. 23rd Int. Power Modulator Symp., 4 pp., Rancho Mirage, CA, USA, Jun. 1998. [3] S. Bae, A. Kwasinski, M. M. Flynn, and R. E. Hebner, "High-power pulse generator with flexible output pattern," IEEE Trans. on Power Elect., vol. 25, no. 7, pp. 1675-1684, Jul. 2010. [4] S. Zabihi, F. Zare, G. Ledwich, A. Ghosh, and H. Akiyama, "A new pulsed power supply topology based on positive buck-boost converters concept," IEEE Trans. on Dielectrics and Electrical Insulation, vol. 17, no. 6, pp. 1901-1911, Dec. 2010. [5] P. Davari, F. Zare, A. Ghosh, and H. Akiyama, "High-voltage modular power supply using parallel and series configurations of flyback converter for pulsed power applications," IEEE Trans. on Plasma Science, vol. 40, no. 10, pp. 2578-2587, Oct. 2012. [6] J. S. Won, et al., "Characteristics of the forward type high voltage pulse power supply for lamp type ozonizer," in Proc. Power Conversion Conf., vol.1, pp. 100-103, Osaka, Japan, 2-5 Apr. 2002. [7] Y. Wu, K. Liu, J. Qiu, X. X. Liu, and H. Xiao, "Repetitive and high voltage marx generator using solid-state devices," IEEE Trans. on Dielectrics and Electrical Insulation, vol. 14, no. 4, pp. 937-940, Aug. 2007. [8] T. Heeren, et al., "Novel dual marx generator for micro plasma applications," IEEE Trans. on Plasma Science, vol. 33, no. 4, pp. 1205-1209, Aug. 2005. [9] D. Wang, J. Qiu, and K. Liu, "All-solid-state repetitive pulsed-power generator using IGBT and magnetic compression switches," IEEE Trans. Plasma Sci., vol. 38, no. 10, pp. 2633-2638, Oct. 2010. [10] H. Canacsinha, L. M. Redondo, and J. F. Silva, "New solid-state marx technology for bipolar repetitive high-voltage pulses," in Proc. IEEE Power Electronics Specialists Conf., pp. 791-795, Rhodes, Greece, 15-19 Jun. 2008. [11] A. Alijani, J. Adabi, and M. Rezanejad, "A bipolar high-voltage pulsed-power supply based on capacitor-switch voltage multiplier," IEEE Trans. on Plasma Sci., vol. 44, no. 11, pp. 1820-1824, Nov. 2016. [12] M. Rezanejad, A. Sheikholeslami, and J. Adabi, "High-voltage modular switched capacitor pulsed power generator," IEEE Trans. on Plasma Science, vol. 42, no. 5, pp. 1373-1379, May 2014. [13] M. Ramezani, M. Rezanejad, and A. Sheikholeslami, "A new modular bipolar high-voltage pulse generator," IEEE Trans. on Industrial Electronics, vol. 64, no. 2, pp. 1195-1203, Feb. 2017. [14] R. Khosravi and M. Rezanejad, "A new pulse generator with high voltage gain and reduced components," IEEE Trans. on Industrial Electronics, vol. 66, no. 4, pp. 2795-2802, Apr. 2019.m.h.n.RasoulRahmani116202331732510.66224/ijece.29261.20.4.317http://ijece.org/fa/Article/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261http://ijece.org/fa/Article/Download/29261[1] D. Deslandes and K. Wu, "Integrated microstrip and rectangular waveguide in planar form," IEEE Microwave and Wireless Components Letters, vol. 11, no. 2, pp. 68-70, Feb. 2001. [2] M. Bozzi, A. Georgiadis, and K. Wu, "Review of substrate-integrated waveguide circuits and antennas," IET Microwave Antennas and Propagation, vol. 5, no. 8, pp. 909-920, Jun. 2011. [3] J. Chen, B. Wu, L. Jiang, and C. Liang, "A compact hexagonal dual-band substrate integrated waveguide filter based on extracted-pole technique," Microwave and Optical Technology Letters, vol. 53, no. 3, pp. 562-565, Jan. 2011. [4] Z. Xu, G. Zhang, H. Xia, and M. Xu, "Novel hexagonal dual-mode substrate integrated waveguide filter with source-load coupling," The Scientific World J., vol. 2014, Article ID: 915740, 5 pp., Apr. 2014. [5] Z. Q. Xu, Y. Shi, P. Wang, J. X. Liao, and X. B. Wei, "Substrate integrated waveguide (SIW) filter with hexagonal resonator," J. of Electromagnetic Waves and Applications, vol. 26, no. 11-12, pp. 1521-1527, Aug. 2012. [6] W. Bo, Z. Xu, L. Hao, X. Meijuan, and J. Liao, "Substrate integrated waveguide cross-coupling filter with multilayer hexagonal cavity," in Proc. Int. Workshop on Microwave and Millimeter Wave Circuits and System Technology, pp. 221-224, Chengdu, China, 24-25, Oct. 2013. [7] M. Rezaee and A. R. Attari, "Realization of new single-layer triple-mode substrate integrated waveguide and dual-mode half-mode substrate-integrated waveguide filters using a circular shape perturbation," IET Microwaves, Antennas & Propagation, vol. 7, no. 14, pp. 1120-1127, Nov. 2013. [8] T. Khorand and M. S. Bayati, "Novel half-mode substrate integrated waveguide bandpass filters using semi-hexagonal resonators," International J. of Electronics and Communications, vol. 92, pp. 52-58, Oct. 2018. [9] A. Vahid Sarani, M. H. Neshati, and M. Fazaelifar, "Development of a wideband hexagonal SIW cavity-backed slot antenna array," International J. of Electronics and Communication, vol. 92, pp. 52-58, Sept. 2021. [10] S. A. Razavi and M. H. Neshati, "Development of a linearly polarized cavity-backed antenna using HMSIW technique," IEEE Antennas and Wireless Propagation Letters, vol. 11, pp. 1309-1310, 2012. [11] H. Dashti and M. H. Neshati, "Development of low-profile patch and semi-circular SIW cavity hybrid antennas," IEEE Trans. Antennas Propag., vol. 26, no. 9, pp. 4481-4488, Sept. 2014. [12] R. J. Cameron, C. M. Kudsia, and R. R. Mansour, Microwave Filters for Communication Systems: Fundamentals, Design, and Applications, Hoboken, NJ: Wiley-Inter-Science, 2007. [13] ر. رحمانی، طراحی، شبیه‌سازی و ساخت فیلترهای پهن باند مایکروویو با استفاده از محفظه تشدید شش‌ضلعی با فناوری موجبر مجتمع‌شده در زیرلایه، پایان‌نامه کارشناسی ارشد، دانشگاه فردوسی، مشهد، ایران، شهریور 1396. [14] J. S. Hong, Microstrip Filters for RF/Microwave Applications, Hoboken, NJ: Wiley, 2011. [15] Y. L. Zhang, W. Hong, K. Wu, J. X. Chen, and Z. C. Hao, "Development of compact bandpass filters with SIW triangular cavities," in IEEE Asia-Pacific Microwave Conf. Proceedings, 4 pp., Suzhou, China, 4-7 Dec. 2005. [16] C. Lugo and J. Papapolymerou, "Planar realization of a triple-mode bandpass filter using a multilayer configuration," IEEE Trans. on Microwave Theory and Techniques, vol. 55, no. 2, pp. 296-301, Feb. 2007.mehrnooshKamarzarrinMohammad HosseinRefanپرویزامیری116202326327910.66224/ijece.31828.20.4.263http://ijece.org/fa/Article/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828http://ijece.org/fa/Article/Download/31828[1] A. Dameshghi and M. H. Refan, "A new strategy for short-term power-curve prediction of wind turbine based on PSO-LS-WSVM," Iranian J. of Electrical and Electronic Engineering, vol. 14, no. 4, pp. 392-403, Dec. 2018. [2] م. رحیمی و م. ر. اسماعیلی، "طراحی کنترل‌کننده توان و بهبود میرایی نوسانات پیچشی در توربین بادی kW 710- DFIG نصب‌شده در سایت بینالود،" مجله مهندسی برق دانشگاه تبریز، جلد 46، شماره 4، صص. 123-134، زمستان 1395. [3] A. Dameshghi, M. H. Refan, and P. Amiri, "Wind turbine doubly fed induction generator rotor electrical asymmetry detection based on an adaptive least mean squares filtering of wavelet transform," Wind Engineering, vol. 45, no. 2, pp. 138-159, Apr. 2021. [4] A. Dameshghi and M. H. Refan, "Combination of condition monitoring and prognosis systems based on current measurement and PSO-LS-SVM method for wind turbine DFIGs with rotor electrical asymmetry," Energy Systems, vol. 12, no. 1, pp. 203-232, 2021. [5] Z. Jiang, M. Karimirad, and T. Moan, "Dynamic response analysis of wind turbines under blade pitch system fault, grid loss, and shutdown events," Wind Energy, vol. 17, no. 9, pp. 1385-1409, Sept. 2014. [6] ی. شب‌بویی، ا. ریخته‌گر غیاثی و س. خان‌محمدی، "طراحی کنترل‌کننده‌ تحمل‌پذیر خطای مد لغزشی ترمینال غیر تکین برای سیستم‌های غیر خطی بر مبنای فیلتر کالمن توسعه‌یافته‌ تطبیقی،" مجله مهندسی برق دانشگاه تبریز، جلد 46، شماره 4، صص. 173-183، زمستان 1395. [7] H. Schulte and E. Gauterin, "Fault-tolerant control of wind turbines with hydrostatic transmission using takagi-sugeno and sliding mode techniques," Annual Reviews in Control, vol. 40, pp. 82-92, 2015. [8] J. Lan, R. J. Patton, and X. Zhu, "Fault-tolerant wind turbine pitch control using adaptive sliding mode estimation," Renewable Energy, Part B, vol. 116, pp. 219-231, Feb. 2018. [9] H. Badihi, Y. Zhang, and H. Hong, "Fault-tolerant cooperative control in an offshore wind farm using model-free and model-based fault detection and diagnosis approaches," Applied Energy, vol. 201, pp. 284-307, Sept. 2017. [10] M. Blanke, R. Izadi-Zamanabadi, S. A. Bøgh, and C. P. Lunau, "Fault-tolerant control systems-a holistic view," Control Engineering Practice, vol. 5, no. 5, pp. 693-702, May 1997. [11] R. J. Patton, "Fault-tolerant control system: the 1997 situation," in Proc. of the IFAC Symp. Fault Detection, Supervi sion and Safety, SAFEPROCESS'97, pp. 1033-1055, Kingston Upon Hull, England, Aug. 1997. [12] M. Blanke, W. C. Frei, F. Kraus, J. R. Patton, and M. Staroswiecki, "What is fault-tolerant control?," in IFAC Proc. Volumes, vol. 33, no. 11, pp. 41-52, Jun. 2000. [13] M. Blanke, M. Staroswiecki, and N. E. Wu, "Concepts and methods in fault-tolerant control," in Proc. of the American Control Conf. vol. 4, pp. 2606-2620, Arlington, VA, USA, 25-27 Jun. 2001. [14] J. Jiang, "Fault-tolerant control systems-an introductory overview," Acta Automatica Sinica, vol. 31, no. 1, pp. 161-174, Jan. 2005. [15] R. Isermann, "Fault-diagnosis systems," Springer Verlag, 2006. [16] M. Blanke, M. Kinnaert, J. Lunze, M. Staroswiecki, and J. Schröder, Diagnosis and Fault-Ttolerant Control, vol. 2, Berlin: Springer, 2006. [17] H. Zhao and L. Cheng, "Open-switch fault-diagnostic method for back-to-back converters of a doubly fed wind power generation system," IEEE Trans. on Power Electronics, vol. 33, no. 4, pp. 3452-3461, Apr. 2018. [18] X. You and W. Zhang, "Fault diagnosis of frequency converter in wind power system based on SOM neural network," Procedia Engineering, vol. 29, pp. 3132-3136, 2012. [19] P. Duan, K. G. Xie, L. Zhang, and X. Rong, "Open-switch fault diagnosis and system reconfiguration of doubly fed wind power converter used in a microgrid," IEEE Trans. on Power Electronics, vol. 26, no. 3, pp. 816-821, Mar. 2011. [20] M. Shahbazi, P. Poure, S. Saadate, and M. R. Zolghadri, "FPGA-based fast detection with reduced sensor count for a fault-tolerant three-phase converter," IEEE Trans. on Industrial Informatics, vol. 9, no. 3, pp. 1343-1350, Aug. 2013. [21] W. Sae-Kok, Converter Fault Diagnosis and Post-Fault Operation of a Doubly-Fed Induction Generator for a Wind Turbine, Doctoral Dissertation, University of Strathclyde, 2008. [22] H. Zhao and L. Cheng, "Open-circuit faults diagnosis in back-to-back converters of DF wind turbine," IET Renewable Power Generation, vol. 11, no. 4, pp. 417-424, Mar. 2017. [23] M. Shahbazi, P. Poure, S. Saadate, and M. R. Zolghadri, "FPGA-based reconfigurable control for fault-tolerant back-to-back converter without redundancy," IEEE Trans. on Industrial Electronics, vol. 60, no. 8, pp. 3360-3371, Aug. 2013. [24] S. Xu, S. Tao, W. Zheng, Y. Chai, M. Ma, and L. Ding, "Multiple open-circuit fault diagnosis for back-to-back converter of PMSG wind generation system based on instantaneous amplitude estimation," IEEE Trans. on Instrumentation and Measurement, vol. 70, Article ID: 3512413, 13 pp. 13, 2021. [25] A. Gaillard, P. Poure, and S. Saadate, "FPGA-based reconfigurable control for switch fault tolerant operation of WECS with DFIG without redundancy," Renewable Energy, vol. 55, pp. 35-48, Jul. 2013. [26] M. Shahbazi, P. Poure, S. Saadate, and M. R. Zolghadri, "Five-leg converter topology for wind energy conversion system with doubly fed induction generator," Renewable Energy, vol. 36, no. 11, pp. 3187-3194, Nov. 2011. [27] M. Shahbazi, P. Poure, and S. Saadate, "Real-time power switch fault diagnosis and fault-tolerant operation in a DFIG-based wind energy system," Renewable Energy, Part B, vol. 116, pp. 209-218, Feb. 2018. [28] A. Kontarček, M. Nemec, P. Bajec, and V. Ambrožič, "Single open-phase fault detection with fault-tolerant control of an inverter-fed permanent magnet synchronous machine," Automatika: Journal for Control, Measurement, Electronics, Computing and Communications, vol. 55, no. 4, pp 474-486, 2014. [29] N. M. Freire and A. J. M. Cardoso, "A fault-tolerant direct controlled PMSG drive for wind energy conversion systems," IEEE Trans. on Industrial Electronics, vol. 61, no. 2, pp. 821-834, Feb. 2014. [30] M. N. Soares, Y. Mollet, M. Kinnaert, J. Gyselinck, and J. Helsen, "Multiphysical time-and frequency-domain fault detection and isolation technique for power-electronic converters in DFIG wind turbines," IEEE Trans. on Power Electronics, vol. 36, no. 4, pp. 3793-3802, Apr. 2021. [31] J. Liang, K. Zhang, A. Al-Durra, and D. Zhou, "A novel fault diagnostic method in power converters for wind power generation system," Applied Energy, vol. 266, Article ID: 114851, May 2020. [32] S. Jadidi, H. Badihi, and Y. Zhang, "Passive fault-tolerant model predictive control of AC/DC PWM converter in a hybrid microgrid," IFAC-PapersOnLine, vol. 53, no. 2, pp. 12097-12102, 2020. [33] M. Kamarzarrin, M. H. Refan, and A. Dameshghi, "A new fault-tolerant control of wind turbine pitch system based on ANN model and robust and optimal development of MRAC method," Tabriz J. of Electrical Engineering, vol. 51, no. 1, pp. 83-95, Spring 2021. [34] C. A. Evangelista, F. Valenciaga, and P. Puleston, "Multivariable 2-sliding mode control for a wind energy system based on a double fed induction generator," International J. of Hydrogen Energy, vol. 37, no. 13, pp. 10070-10075, Jul. 2012. [35] M. Kamarzarrin and M. H. Refan, "Intelligent sliding mode adaptive controller design for wind turbine pitch control system using PSO-SVM in presence of disturbance," J. of Control, Automation and Electrical Systems, vol. 31, pp. 912-925, Mar. 2020. [36] J. Liu, X. Chen, and J. Wang, "Sliding mode control to stabilization of a tip-force destabilized shear beam subject to boundary control matched disturbance," Journal of Dynamical and Control Systems, vol. 22, pp. 117-128, 2016.MojtabaNouri Manzar116202330130810.66224/ijece.32263.20.4.301http://ijece.org/fa/Article/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263http://ijece.org/fa/Article/Download/32263[1] A. S. Morse, D. Q. Mayne, and G. C. Goodwin, "Applications of hysteresis switching in parameter adaptive control," IEEE Trans. on Automatic Control, vol. 37, no. 9, pp. 1343-1354, Sep. 1992. [2] H. Jin and M. G. Safonov, "Unfalsified adaptive control: controller switching algorithms for nonmonotone cost functions," International J. of Adaptive Control and Signal Processing, vol. 26, no. 8, pp. 692-704, Aug. 2012. [3] R. Wang, A. Paul, M. Stefanovic, and M. G. Safonov, "Cost detectability and stability of adaptive control systems," International J. of Robust and Nonlinear Control: IFAC-Affiliated J., vol. 17, no. 5-6, pp. 549-561, Mar. 2007. [4] M. G. Safonov and T. C. Tsao, "The unfalsified control concept: a direct path from experiment to controller," In: B. A. Francis and A.R. Tannenbaum, (eds.) Feedback Control, Nonlinear Systems, and Complexity. Lecture Notes in Control and Information Sciences, vol. 202. Springer, Berlin, Heidelberg pp. 196-214, 1995. [5] S. Baldi, G. Battistelli, E. Mosca, and P. Tesi, "Multi-model unfalsified adaptive switching supervisory control," Automatica, vol. 46, no. 2, pp. 249-259, Feb. 2010. [6] S. Baldi, G. Battistelli, E. Mosca, and P. Tesi, "Multi-model unfalsified adaptive switching control: test functionals for stability and performance," International J. of Adaptive Control and Signal Processing, vol. 25, no. 7, pp. 593-612, Jul. 2011. [7] G. Battistelli, J. P. Hespanha, E. Mosca, and P. Tesi, "Model-free adaptive switching control of time-varying plants," IEEE Trans. on Automatic Control, vol. 58, no. 5, pp. 1208-1220, May 2013. [8] S. V. Patil, Y. C. Sung, and M. G. Safonov, "Unfalsified adaptive control for nonlinear time-varying plants," IEEE Trans. on Automatic Control, vol. 67, no. 8, pp. 3892-3904, Aug. 2022. [9] م. نوری منظر و ع. خاکی صدیق، "کنترل نظارتی پیش‌بین ابطال‌ناپذیر مدل چندگانه،" مجله کنترل، جلد 9، شماره 2، صص. 24-14، تابستان 1394. [10] B. Sadeghi Forouz, M. Nouri Manzar, and A. Khaki-Sedigh, "Multiple model unfalsified adaptive generalized predictive control based on the quadratic inverse optimal control concept," Optimal Control Applications and Methods, vol. 42, no. 3, pp. 769-785, May/Jun. 2021. [11] M. Nouri Manzar, G. Battistelli, and A. Khaki-Sedigh, "Input-constrained multi-model unfalsified switching control," Automatica, vol. 83, pp. 391-395, Sept. 2017. [12] M. Nouri Manzar and A. Khaki-Sedigh, "Self-falsification in multimodel unfalsified adaptive switching control," International J. of Adaptive Control and Signal Processing, vol. 31, no. 11, pp. 1723-1739, Nov. 2017. [13] S. I. Habibi, A. Khaki-Sedigh, and M. Nouri Manzar, "Performance enhancement of unfalsified adaptive control strategy using fuzzy logic," International J. of Systems Science, vol. 50, no. 15, pp. 2752-2763, 2019. [14] S. I. Habibi and A. Bidram, "Unfalsified switching adaptive voltage control for islanded microgrids," IEEE Trans. on Power Systems, vol. 37, no. 5, pp. 3394-3407, Sep. 2022. [15] A. Hokmabadi and M. Khodabandeh, "Unfalsified control design using a generalized cost function for a quadrotor," Aircraft Engineering and Aerospace Technology, vol. 93, no. 2, pp. 241-250, 2021. [16] C. de Persis and P. Tesi, "Formulas for data-driven control: stabilization, optimality, and robustness," IEEE Trans. on Automatic Control, vol. 65, no. 3, pp. 909-924, Mar. 2019. [17] H. Kwakernaak, The Polynomial Approach to H∞-Optimal Regulation, in H∞-Control Theory, Springer, pp. 141-221, 1991. [18] M. Grant and S. Boyd, CVX: Matlab Software for Disciplined Convex Programming, Version 2.2, 2020.FarhadRezaee-AlamAbdolsamadHamidiVahidNaeini116202329330010.66224/ijece.34184.20.4.293http://ijece.org/fa/Article/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184http://ijece.org/fa/Article/Download/34184[1] M. Al Saaideh, N. Alatawneh, and M. Al Janaideh, "Multi-objective optimization of a reluctance actuator for precision motion applications," J. of Magnetism and Magnetic Materials, vol. 546, Article ID: 168652, Mar. 2022. [2] F. Mahmouditabar, A. Vahedi, and P. Ojaghlu, "Investigation of demagnetization phenomenon in novel ring winding AFPM motor with modified algorithm," J. of Magnetism and Magnetic Materials, vol. 491, Article ID: 165539, Dec. 2019. [3] B. Asad, T. Vaimann, A. Belahcen, A. Kallaste, A. Rassõlkin, and M. N. Iqbal, "Modified winding function-based model of squirrel cage induction motor for fault diagnostics," IET Electric Power Application, vol. 14, no. 9, pp. 1722-1734, Sept. 2020. [4] M. Ojaghi, M. Sabouri, and J. Faiz, "Performance analysis of squirrel-cage induction motors under broken rotor bar and stator inter-turn fault conditions using analytical modeling," IEEE Trans. on Magnetics, vol. 54, no. 11, Article ID: 8203705, Nov. 2018. [5] A. Waheed, B. Kim, and Y. H. Cho, "Optimal design of line start permanent magnet synchronous motor based on magnetic equivalent parameters," J. of Electrical Engineering & Technology, vol. 15, pp. 2111-2119, Sep. 2020. [6] H. Saneie and Z. Nasiri-Gheidari, "Performance analysis of outer-rotor single-phase induction motor based on magnetic equivalent circuit (MEC)," IEEE Trans. on Industrial Electronics, vol. 68, no. 2, pp. 1046-1054, Feb. 2021. [7] K. Boughrara, N. Takorabet, R. Ibtiouen, O. Touhami, and F. Dubas, "Analytical analysis of cage rotor induction motors in healthy, defective, and broken bars conditions," IEEE Trans. on Magnetics, vol. 51, no. 2, Article ID: 8200317, Feb. 2015. [8] A. Mollaeian, E. Ghosh, H. Dhulipati, J. Tjong, and N. C. Kar, "3-D sub-domain analytical model to calculate magnetic flux density in induction machines with semi-closed slots under no-load condition," IEEE Trans. on Magnetics, vol. 53, no. 6, Article ID: 7206905, Jun. 2017. [9] M. M. Kiani, W. Wang, and W. J. Lee, "Elimination of system-induced torque pulsations in doubly-fed induction generators via field reconstruction method," IEEE Trans. on Energy Conversion, vol. 30, no. 3, pp. 1228-1236, Sep. 2015. [10] D. Wu, S. D. Pekarek, and B. Fahimi, "A field reconstruction technique for efficient modeling of the fields and forces within induction machines," IEEE Trans. on Energy Conversion, vol. 24, no. 2, pp. 366-374, Jun. 2009. [11] T. F. Megahed, "Analytical approach to estimate the polyphase induction machine performance," J. of Magnetism and Magnetic Materials, vol. 514, Article ID: 167119, Nov. 2020. [12] A. Balamurali, C. Lai, A. Mollaeian, V. Loukanov, and N. C. Kar, "Analytical investigation of magnet eddy current losses in interior permanent magnet motor using modified winding function theory accounting for pulse width modulation harmonics," IEEE Trans. on Magnetics, vol. 52, no. 7, Article ID: 8106805, Jul. 2016. [13] J. Faiz and F. Rezaee-Alam, "A new hybrid analytical model based on winding function theory for analysis of surface mounted permanent magnet motors," The International J. for Computation and Mathematics in Electrical and Electronic Engineering, vol. 38, no. 2, pp. 745-758, May 2019. [14] F. Rezaee-Alam, B. Rezaeealam, and S. M. M. Moosavi, "An improved magnetic equivalent circuit model for electromagnetic modeling of electric machines," Iranian J. of Electrical and Electronic Engineering, vol. 17, no. 3, pp. 1965-1965, Sept. 2021. [15] M. Farhadian, M. Moallem, and B. Fahimi, "Analytical calculation of magnetic field components in synchronous reluctance machine accounting for rotor flux barriers using combined conformal mapping and magnetic equivalent circuit methods," J. of Magnetism and Magnetic Materials, vol. 505, Article ID: 166762, Jul. 2020. [16] Z. Zhang, C. Xia, Y. Yan, Q. Geng, and T. Shi, "A hybrid analytical model for open-circuit field calculation of multilayer interior permanent magnet machines," J. of Magnetism and Magnetic Materials, vol. 435, pp. 136-145, Aug. 2017. [17] S. Ouagued, Y. Amara, and G. Barakat, "Comparison of hybrid analytical modeling and reluctance network modeling for pre-design purposes," Mathematics and Computers in Simulation, vol. 130, pp. 3-21, Dec. 2016. [18] S. Li, W. Tong, M. Hou, S. Wu, and R. Tang, "Analytical model for no-load electromagnetic performance prediction of V-shape IPM motors considering nonlinearity of magnetic bridges," IEEE Trans. on Energy Conversion, vol. 37, no. 2, pp. 901-911, Jun. 2022. [19] B. Ge, W. Liu, J. Dong, and M. Liu, "Extending winding function theory to incorporate secondary effects in the design of induction machines and drives," IEEE J. of Emerging and Selected Topics in Power Electronics, vol. 10, no. 2, pp. 1915-1924, Apr. 2022. [20] B. Ladghem-Chikouche, K. Boughrara, F. Dubas, and R. Ibtiouen, "Two-dimensional hybrid model for magnetic field calculation in electrical machines: exact subdomain technique and magnetic equivalent circuit," International J. for Computation and Mathematics in Electrical and Electronic Engineering (COMPEL), vol. 40, no. 3, pp. 535-560, Aug. 2021. [21] Z. Li, X. Huang, L. Wu, H. Zhang, T. Shi, Y. Yan, B. Shi, and G. Yang, "An improved hybrid field model for calculating on-load performance of interior permanent-magnet motors," IEEE Trans. on Industrial Electronics, vol. 68, no. 10, pp. 9207-9217, Oct. 2021.PeymanMirzaeipouresmaeelrokrokMohsenSanieiSyed Qudrat Allahseifosadat116202324526210.66224/ijece.36435.20.4.245http://ijece.org/fa/Article/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435http://ijece.org/fa/Article/Download/36435[1] M. Mamdouh and M. A. Abido, "Predictive current control of asymmetrical sixphase induction motor without weighting factors," Alexandria Engineering J., vol. 61, no. 1, pp. 3793-3804, Sep. 2022. [2] B. M. Shihab, M. Tousizadeh, and H. S. Che, "Continuous and discontinuous PWM methods for symmetrical six-phase induction motor with single isolated neutral," Arab. J. Sci. Eng., vol. 45, no. 3, pp. 1885-1895, Apr. 2020. [3] F. Wang, Z. Zhang, X. Mei, J. Rodriguez, and R. Kennel, "Advanced control strategies of induction machine: field oriented control, direct torque control and model predictive control," Energies, vol. 11, no. 2, pp. 120-128, Jul. 2018. [4] F. Wang, X. Mei, J. Rodriguez, and R. Kennel, "Model predictive control for electrical drive systems-an overview," CES Trans. Electr. Mach. Syst., vol. 1, no. 3, pp. 219-230, Mar. 2017. [5] S. A. Davari, D. A. Khaburi, and R. Kennel, "An improved FCS-MPC algorithm for an induction motor with an imposed optimized weighting factor," IEEE Trans. Power Electron., vol. 27, no. 3, pp. 1540-1551, Apr. 2012. [6] P. Gonçalves, S. Cruz, and A. Mendes, "Finite control set model predictive control of six-phase asymmetrical machines an overview," Energies, vol. 12, no. 4, pp. 4693-4703, Aug. 2019. [7] O. Gonzalez, et al., "Model predictive current control of six-phase induction motor drives using virtual vectors and space vector modulation," IEEE Trans. on Power Electronics, vol. 37, no. 7, pp. 7617-7628, Mar. 2022. [8] H. S. Che, A. S. Abdel-Khalik, S. Member, and E. Levi, "Parameter estimation of asymmetrical six-phase induction machines using modified standard tests," IEEE Trans. Ind. Electron., vol. 64, no. 8, pp. 6075-6085, Nov. 2017. [9] G. Rezazadeh, F. Tahami, G. Capolino, Z. Nasiri-Gheidari, H. Henao, and M. Sahebazamani, "Improved design of a six-phase squirrel cage induction motor with pseudo-concentrated windings," IEEE J. of Emerging and Selected Topics in Industrial Electronics, vol. 21, no. 3, pp. 1-11, May 2021. [10] X. Sun, T. Li, X. Tian, and J. Zhu, "Fault-tolerant operation of a six-phase permanent magnet synchronous hub motor based on model predictive current control with virtual voltage vectors," IEEE Trans. on Energy Conversion, vol. 37, no. 1, pp. 337-346, Mar. 2022. [11] M. Bermudez, C. Martin, I. Gonzalez-Prieto, M. J. Duran, M. R. Arahal, and F. Barrero, "Predictive current control in electrical drives: an illustrated review with case examples using a five-phase induction motor drive with distributed windings," IET Electr. Power Appl., vol. 14, no. 8, pp. 1327-1338, Jun. 2020. [12] A. Al-Hitmi, K. Rahman, and N. Al-Emadi, "Control and modulation of three to asymmetrical six-phase matrix converters based on space vectors," J. of Power Electronics, vol. 19, no. 2, pp. 475-486, Mar. 2019. [13] A. Habib, A. Shawier, M. Mamdouh, A. S. Abdel-Khalik, M. S. Hamad, and S. Ahmed, "Predictive current control based pseudo six-phase induction motor drive," Alexandria Engineering J., vol. 61, no. 5, pp. 3937-3948, Oct. 2022. [14] J. Paredes, B. Prieto, M. Satrustegui, I. Elosegui, and P. Gonzalez, "Improving the performance of a 1-MW induction machine by optimally shifting from a three-phase to a six-phase machine design by rearranging the coil connections," IEEE Trans. Ind. Electron., vol. 68, no. 3, pp. 1035-1045, Feb. 2021. [15] A. Gonzalez-Prieto, I. Gonzalez-Prieto, A. G. Yepes, M. J. Duran, and J. Doval-Gandoy, "On the advantages of symmetrical over asymmetrical multiphase ac drives with even phase number using direct controllers," IEEE Trans. on Industrial Electronics, vol. 69, no. 8, pp. 7639-7650, Aug. 2022. [16] A. Shawier, A. Habib, M. Mamdouh, A. S. Abdel-Khalik, and K. H. Ahmed, "Assessment of predictive current control of six-phase induction motor with different winding configurations," IEEE Access, vol. 9, pp. 81125-81138, 2021. [17] A. González-Prieto, I. González-Prieto, M. J. Duran, J. J. Aciego, and P. Salas-Biedma, "Current harmonic mitigation using a multi-vector solution for MPC in six-phase electric drives," IEEE Access, vol. 9, no. 2, pp. 117761-117771, Aug. 2021. [18] M. Mamdouh and M. A. Abido, "Weighting factor elimination for predictive current control of asymmetric six-phase induction motor," in Proc. IEEE Int. Conf. on Environment and Electrical Engineering and IEEE Industrial and Commercial Power Systems Europe, EEEIC/I&CPS Europe’20, vol. 11, 6 pp., Madrid, Spain, 9-12 Jun. 2020. [19] M. S. Abdel-Majeed, et al., "General current control of six-phase-based non-isolated integrated on-board charger with low order harmonic compensation," Sustainability, vol. 14, no. 3, Article ID: 1088, 2022. [20] M. J. Durán, I. Gonzalez-Prieto, and A. Gonzalez-Prieto, "Large virtual voltage vectors for direct controllers in six-phase electric drives," International J. of Electrical Power & Energy Systems, vol. 125, Article ID: 106425, Feb. 2021. [21] J. J. Aciego, I. G. Prieto, and M. J. Duran, "Model predictive control of six-phase induction motor drives using two virtual voltage vectors," IEEE J. of Emerging and Selected Topics in Power Electronics, vol. 7, no. 1, pp. 321-330, Oct. 2019. [22] O. Gonzalez, et al., "Predictive-fixed switching current control strategy applied to six-phase induction machine," Energies, vol. 12, no. 12, Article ID: 2294, 2019. [23] Y. Wang, A. Biswas, R. Rodriguez, Z. Keshavarz-Motamed, and A. Emadi, "Hybrid electric vehicle specific engines: state-of-the-art review," Energy Reports, vol. 8, no. 1, pp. 832-851, Mar. 2022.AbdollahMirzabeigiAliKazemyMehdiRamezaniSeyed MohammadAzimi116202328029210.66224/ijece.38188.20.4.280http://ijece.org/fa/Article/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188http://ijece.org/fa/Article/Download/38188[1] S. M. Azimi and S. Lotfifard, "Supplementary controller for inverter-based resources in weak power grids," IEEE Trans. on Smart Grid, vol. 13, no. 4, pp. 2886 - 2896, Jul. 2022. [2] S. Derakhshan, M. Shafiee-Rad, Q. Shafiee, and M. R. Jahed-Motlagh, "Decentralized robust voltage control of islanded AC microgrids: an LMI-based H∞ approach," in Proc. 11th IEEE Power Electronics, Drive Systems, and Technologies Conf., PEDSTC’20, 6 pp., Tehran, Iran, 4-6 Feb. 2020. [3] A. Bidram and A. Davoudi, "Hierarchical structure of microgrids control system," IEEE Trans. on Smart Grid, vol. 3, no. 4, pp. 1963-1976, Dec. 2012. [4] A. Bidram, F. L. Lewis, and A. Davoudi, "Distributed control systems for small-scale power networks: using multiagent cooperative control theory," IEEE Control Systems Magazine, vol. 34, no. 6, pp. 56-77, Dec. 2014. [5] Q. Shafiee, J. M. Guerrero, and J. C. Vasquez, "Distributed secondary control for islanded microgrids-a novel approach," IEEE Trans. on Power Electronics, vol. 29, no. 2, pp. 1018-1031, Feb. 2014. [6] A. Bidram, A. Davoudi, F. L. Lewis, and Z. Qu, "Secondary control of microgrids based on distributed cooperative control of multi-agent systems," IET Generation, Transmission & Distribution, vol. 7, no. 8, pp. 822-831, Aug. 2013. [7] Z. Shahbazi, A. Ahmadi, A. Karimi, and Q. Shafiee, "Performance and vulnerability of distributed secondary control of AC microgrids under cyber-attack," in Proc. 7th IEEE Int, Conf. on Control, Instrumentation and Automation, ICCIA’21, 6 pp., Tabriz, Iran, 23-24 Feb. 2021. [8] X. Wang and M. Lemmon, "On event design in event-triggered feedback systems," Automatica, vol. 47, no. 10, pp. 2319-2322, Oct. 2011. [9] Z. Gu, Z. Huan, D. Yue, and F. Yang, "Event-triggered dynamic output feedback control for networked control systems with probabilistic nonlinearities," Information Sciences, vol. 457-458, pp. 99-112, Aug. 2018. [10] Y. L. Wang, P. Shi, C. C. Lim, and Y. Liu, "Event-triggered fault detection filter design for a continuous-time networked control system," IEEE Trans. on Cybernetics, vol. 46, no. 12, pp. 3414-3426, Dec. 2016. [11] M. S. Mahmoud, M. M. Hamdan, and U. A. Baroudi, "Modeling and control of cyber-physical systems subject to cyber attacks: a survey of recent advances and challenges," Neurocomputing, vol. 338, pp. 101-115, Apr. 2019. [12] H. Yan, J. Wang, H. Zhang, H. Shen, and X. Zhan, "Event-based security control for stochastic networked systems subject to attacks," IEEE Trans. on Systems, Man, and Cybernetics: Systems, vol. 50, no. 11, pp. 4643-4654, Nov. 2018. [13] Y. Yuan, H. Yuan, L. Guo, H. Yang, and S. Sun, "Resilient control of networked control system under DoS attacks: a unified game approach," IEEE Trans. on Industrial Informatics, vol. 12, no. 5, pp. 1786-1794, Oct. 2016. [14] H. Modares, B. Kiumarsi, F. L. Lewis, F. Ferrese, and A. Davoudi, "Resilient and robust synchronization of multiagent systems under attacks on sensors and actuators," IEEE Trans. on Cybernetics, vol. 50, no. 3, pp. 1240-1250, Mar. 2020. [15] X. M. Zhang, Q. L. Han, X. Ge, and L. Ding, "Resilient control design based on a sampled-data model for a class of networked control systems under denial-of-service attacks," IEEE Trans. on Cybernetics, vol. 50, no. 8, pp. 3616-3626, Aug. 2020. [16] A. Teixeira, D. Pérez, H. Sandberg, and K. H. Johansson, "Attack models and scenarios for networked control systems," in Proc. of the 1st Int. Conf. on High Confidence Networked Systems, HiCoNS’12,pp. 55-64, Beijing, China, 17-18 Apr. 2012. [17] E. Mousavinejad, F. Yang, Q. L. Han, and L. Vlacic, "A novel cyber attack detection method in networked control systems," IEEE Trans. on Cybernetics, vol. 48, no. 11, pp. 3254-3264, Nov. 2018. [18] S. Zuo, T. Altun, F. L. Lewis, and A. Davoudi, "Distributed resilient secondary control of DC microgrids against unbounded attacks," IEEE Trans. on Smart Grid, vol. 11, no. 5, pp. 3850-3859, Sept. 2020. [19] B. Wang, Q. Sun, and D. Ma, "A periodic event-triggering reactive power sharing control in an islanded microgrid considering DoS attacks," in Proc. of the 15th IEEE Conf. on Industrial Electronics and Applications, ICIEA’20, pp. 170-175, Kristiansand, Norway, 9-13 Nov. 2020. [20] R. Lu and J. Wang, "Distributed control for AC microgrids with false data injection attacks and time delays," in Proc. of the E3S Web of Conf., vol. 194, Article ID: 03023, Shanghai, China, 18-20 Sept. 2020. [21] S. Tan, P. Xie, J. M. Guerrero, and J. C. Vasquez, "False data injection cyber-attacks detection for multiple DC microgrid clusters," Applied Energy, vol. 310, Article ID: 118425, Mar. 2022. [22] C. De Persis and P. Tesi, "Input-to-state stabilizing control under denial-of-service," IEEE Trans. on Automatic Control, vol. 60, no. 11, pp. 2930-2944, Nov. 2015. [23] B. Wang, Q. Sun, R. Han, and D. Ma, "Consensus-based secondary frequency control under denial-of-service attacks of distributed generations for microgrids," J. of the Franklin Institute, vol. 358, no. 1, pp. 114-130, Jan. 2019. [24] P. Chen, S. Liu, B. Chen, and L. Yu, "Multi-agent reinforcement learning for decentralized resilient secondary control of energy storage systems against DoS attacks," IEEE Trans. on Smart Grid, vol. 13, no. 3, pp. 1739-1750, May 2022. [25] A. Karimi, A. Ahmadi, Z. Shahbazi, H. Bevrani, and Q. Shafiee, "On the impact of cyber-attacks on distributed secondary control of DC microgrids," in Proc. 10th of the IEEE Smart Grid Conf., SGC’20, , 6 pp., Kashan, Iran, 16-17 Dec. 2020. [26] X. Chen, J. Zhou, M. Shi, Y. Chen, and J. Wen, "Distributed resilient control against denial of service attacks in DC microgrids with constant power load," Renewable and Sustainable Energy Reviews, vol. 153, Article ID: 111792, Jan. 2022. [27] S. Liu, Z. Hu, X. Wang, and L. Wu, "Stochastic stability analysis and control of secondary frequency regulation for islanded microgrids under random denial of service attacks," IEEE Trans. on Industrial Informatics, vol. 15, no. 7, pp. 4066-4075, Jul. 2018. [28] N. Pogaku, M. Prodanovic, and T. C. Green, "Modeling, analysis and testing of autonomous operation of an inverter-based microgrid," IEEE Trans. on Power Electronics, vol. 22, no. 2, pp. 613-625, Mar. 2007. [29] A. Bidram, A. Davoudi, F. L. Lewis, and J. M. Guerrero, "Distributed cooperative secondary control of microgrids using feedback linearization," IEEE Trans. on Power Systems, vol. 28, no. 3, pp. 3462-3470, Aug. 2013. [30] J. W. Simpson-Porco, et al., "Secondary frequency and voltage control of islanded microgrids via distributed averaging," IEEE Trans. on Industrial Electronics, vol. 62, no. 11, pp. 7025-7038, Nov. 2015. [31] H. Z. Frank L. Lewis, Kristian Hengster-Movric, and A. Das, Cooperative Control of Multi-Agent Systems Optimal and Adaptive Design Approaches, SpringerLink, 2014. [32] F. Guo, C. Wen, J. Mao, J. Chen, and Y. D. Song, "Distributed cooperative secondary control for voltage unbalance compensation in an islanded microgrid," IEEE Trans. on Industrial Informatics, vol. 11, no. 5, pp. 1078-1088, Oct. 2015. [33] H. Cai, F. L. Lewis, G. Hu, and J. Huang, "The adaptive distributed observer approach to the cooperative output regulation of linear multi-agent systems," Automatica, vol. 75, pp. 299-305, Jan. 2017. [34] J. C. Vasquez, J. M. Guerrero, J. Miret, M. Castilla, and L. G. De Vicuna, "Hierarchical control of intelligent microgrids," IEEE Industrial Electronics Magazine, vol. 4, no. 4, pp. 23-29, Dec. 2010. [35] J. P. Lopes, C. Moreira, and A. Madureira, "Defining control strategies for microgrids islanded operation," IEEE Trans. on Power Systems, vol. 21, no. 2, pp. 916-924, May 2006. [36] A. Kazemy, J. Lam, and Z. Chang, "Adaptive event-triggered mechanism for networked control systems under deception attacks with uncertain occurring probability," International J. of Systems Science, vol. 21, no. 7, pp. 1426-1439, 2020. [37] H. Zhang, F. L. Lewis, and A. Das, "Optimal design for synchronization of cooperative systems: state feedback, observer and output feedback," IEEE Trans. on Automatic Control, vol. 56, no. 8, pp. 1948-1952, Aug. 2011. [38] Z. Qu, Cooperative Control of Dynamical Systems: Applications to Autonomous Vehicles, Springer Science & Business Media, 2009.