ijece-140502292114050229212923CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagNashriyyah -i Muhandisi -i Barq va Muhandisi -i Kampyutar -i Iranijece168237451092021192مهرنوش میرحاجمریممسجدیمحمدفرزانصباحی109202114214810.66224/ijece.28704.19.2.142http://ijece.org/fa/Article/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704http://ijece.org/fa/Article/Download/28704 [1] T. A. Zewde and M. C. Gursoy, "Energy-efficient time allocation for wireless energy harvesting communication networks," in Proc. IEEE Globecom Workshops, 6 pp., Washington, DC, USA, 2-4 Dec. 2016. [2] G. Yang, C. K. Ho, R. Zhang, and Y. L. Guan, "Throughput optimization for massive MIMO systems powered by wireless energy transfer," IEEE J. on Selected Areas in Communications, vol. 33, no. 8, pp. 1640-1650, Aug. 2015. [3] M. Zheng, W. Liang, and H. Yu, "Utility-based resource allocation in wireless-powered communication networks," IEEE Systems J., vol. 12, no. 4, pp. 3881-3884, Dec. 2018. [4] H. Kim, H. Lee, S. Jang, J. Moon, and I. Lee, "Maximization of minimum rate for wireless powered communication networks in interference channel," IEEE Communications Letters, vol. 22, no. 8, pp. 1648-1651, Aug. 2018. [5] Z. Yang, W. Xu, Y. Pan, C. Pan, and M. Chen, "Optimal fairness-aware time and power allocation in wireless powered communication networks," IEEE Trans. on Communications, vol. 66, no. 7, pp. 3122-3135, Jul. 2018. [6] X. Lu, P. Wang, D. Niyato, D. I. Kim, and Z. Han, "Wireless networks with RF energy harvesting: a contemporary survey," IEEE Communications Surveys & Tutorials, vol. 17, no. 2, pp. 757-789, Second Quarter. 2014. [7] I. Ahmed, M. M. Butt, C. Psomas, A. Mohamed, I. Krikidis, and M. Guizani, "Survey on energy harvesting wireless communications: challenges and opportunities for radio resource allocation," Computer Networks, vol. 88, pp. 234-248, Sept. 2015. [8] T. C. Rao and K. Geetha, "Categories, standards and recent trends in wireless power transfer: a survey," Indian J. of Science and Technology, vol. 9, no. 20, pp. 1-11, May 2016. [9] S. Leng, D. W. K. Ng, N. Zlatanov, and R. Schober, "Multi-objective beamforming for energy-efficient SWIPT systems," in Proc. Int. Conf. on Computing, Networking and Communications, ICNC'16, 7 pp., Kauai, HI, USA, 15-18 Feb. 2016. [10] H. Lee, K. J. Lee, H. Kim, B. Clerckx, and I. Lee, "Resource allocation techniques for wireless powered communication networks," in Proc. IEEE Int. Conf. on Communications, ICC'16, 6 pp., Kuala Lumpur, Malaysia, 22-27 May 2016. [11] D. K. P. Asiedu, H. Lee, and K. J. Lee, "Transmit power minimization for a multi-hop SWIPT decode-and-forward sensor network," in Proc IEEE 90th Vehicular Technology Conf., VTC'19, 5 pp., Honolulu, HI, USA, 22-25 Sept. 2019. [12] H. Ju and R. Zhang, "Throughput maximization in wireless powered communication networks," IEEE Trans. on Wireless Communications, vol. 13, no. 1, pp. 418-428, Jan. 2013. [13] L. Liu, R. Zhang, and K. C. Chua, "Multi-antenna wireless powered communication with energy beamforming," IEEE Trans. on Communications, vol. 62, no. 12, pp. 4349-4361, Dec. 2014. [14] X. Kang, C. K. Ho, and S. Sun, "Full-duplex wireless-powered communication network with energy causality," IEEE Trans. on Wireless Communications, vol. 14, no. 10, pp. 5539-5551, Oct. 2015. [15] H. Ju and R. Zhang, "Optimal resource allocation in full-duplex wireless-powered communication network," IEEE Trans. on Communications, vol. 62, no. 10, pp. 3528-3540, Oct. 2014. [16] Z. Hadzi-Velkov, I. Nikoloska, G. K. Karagiannidis, and T. Q. Duong, "Wireless networks with energy harvesting and power transfer: joint power and time allocation," IEEE Signal Processing Letters, vol. 23, no. 1, pp. 50-54, Jan. 2015. [17] F. Zhao, L. Wei, and H. Chen, "Optimal time allocation for wireless information and power transfer in wireless powered communication systems," IEEE Trans. on Vehicular Technology, vol. 65, no. 3, pp. 1830-1835, Mar. 2015. [18] E. Boshkovska, D. W. K. Ng, N. Zlatanov, A. Koelpin, and R. Schober, "Robust resource allocation for MIMO wireless powered communication networks based on a non-linear EH model," IEEE Trans. on Communications, vol. 65, no. 5, pp. 1984-1999, May 2017. [19] D. K. P. Asiedu, S. Mahama, C. Song, D. Kim, and K. J. Lee, "Beamforming and resource allocation for multiuser full-duplex wireless-powered communications in IoT networks," IEEE Internet of Things J., vol. 7, no. 12, pp. 11355-11370, Dec. 2020. [20] I. Hameed, P. V. Tuan, M. R. Camana, and I. Koo, "Optimal energy beamforming to minimize transmit power in a multi-antenna wireless powered communication network," Electronics, vol. 10, no. 4, pp. 2079-9292, 2021. [21] P. Ramezani and A. Jamalipour, "Two-way dual-hop WPCN with a practical energy harvesting model," IEEE Trans. on Vehicular Technology, vol. 69, no. 7, pp. 8013-8017, Jul. 2020. [22] H. Lee, K. J. Lee, H. B. Kong, and I. Lee, "Sum-rate maximization for multiuser MIMO wireless powered communication networks," IEEE Trans. on Vehicular Technology, vol. 65, no. 11, pp. 9420-9424, Nov. 2016. [23] M. Maleki, A. M. D. Hoseini, and M. Masjedi, "Performance analysis of SWIPT relay systems over Nakagami-m fading channels with non-linear energy harvester and hybrid protocol," in Proc. Iranian Conf. on Electrical Engineering, ICEE'18, pp. 610-615, Mashhad, Iran, 8-10 May 2018. [24] S. Pejoski, Z. Hadzi-Velkov, and R. Schober, "Optimal power and time allocation for WPCNs with piece-wise linear EH model," IEEE Wireless Communications Letters, vol. 7, no. 3, pp. 364-367, Jun. 2017. [25] E. Boshkovska, D. W. K. Ng, N. Zlatanov, and R. Schober, "Practical non-linear energy harvesting model and resource allocation for SWIPT systems," IEEE Communications Letters, vol. 19, no. 12, pp. 2082-2085, Dec. 2015. [26] Y. Dong, M. J. Hossain, and J. Cheng, "Performance of wireless powered amplify and forward relaying over Nakagami-m fading channels with nonlinear energy harvester," IEEE Communications Letters, vol. 20, no. 4, pp. 672-675, Apr. 2016. [27] S. Boyd and L. Vandenberghe, Convex Optimization, Cambridge University Press, 2004. [28] M. Grant and S. Boyd, CVX: Matlab Software for Disciplined Convex Programming, Version 2.1, 2014.Mohsen Jahantighmajidmoazzami10920219910810.66224/ijece.28937.19.2.99http://ijece.org/fa/Article/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937http://ijece.org/fa/Article/Download/28937[1] J. Armstrong, Principles of Forecasting: A Handbook for Researchers and Practitioners, Springer; 2001. [2] V. Genre, G. Kenny, A. Meyler, and A. Timmermann, "Combining expert forecasts: can anything beat the simple average?" Int J. Forecast, vol. 29, no. 1, pp. 108-121, Jan./Mar. 2013. [3] K. Wallis, "Combining forecasts forty years later," Applied Financial Economics, vol. 21, no. 1-2, pp. 33-41, 2011. [4] L. Rokach, "Ensemble-based classifiers," Artificial Intelligence Review, vol. 33, pp. 1-39, 2010. [5] O. Abedinia, N. Amjady, and H. Zareipour, "A new feature selection technique for load and price forecast of electrical power systems," IEEE Trans. Power Syst, vol. 32, no. 1, pp. 62-74, Jan. 2017. [6] G. Li, Y. Li, and F. Roozitalab, "Midterm load forcasting: a multistep approach based on phase space reconstruction and support vector machine," IEEE Systems Journal, vol. 14, no. 4, pp. 4967-4977, Dec. 2020. [7] D. K. Ranaweera, G. G. Karady, and R. G. Farmer, "Effect of probabilistic inputs on neural network-based electric load forecasting," IEEE Trans. Neural Network, vol. 7, no. 6, pp. 1528-1532, Nov. 1996. [8] W. Zhang, H. Quan, and D. Srinivasan, "An improved quantile regression neural network for probabilistic load forecasting," IEEE Trans. Smart Grid, vol. 10, no. 4, pp. 4425-4434, Jul. 2019. [9] Z. Deng, B. Wang, Y. Xu, T. Xu, C. Liu, and Z. Zhu, "Multi-scale convolutional neural network with time-cognition for multi-step short-term load forecasting," IEEE Access, vol. 7, pp. 88058-88071, Jul. 2019. [10] Z. Yu, Z. Niu, W. Tang, and Q. Wu, "Deep learning for daily peak load forecasting-a novel gated recurrent neural network combining dynamic time warping," IEEE Access, vol. 7, pp. 17184-17194, Jan. 2019. [11] D. Niu, Y. Wang, and D. D. Wu, "Power load forecasting using support vector machine and ant colony optimization," Elsevier Expert Systems with Applications, vol. 37, no. 3, pp. 2531-2539, Mar. 2010. [12] N. Amjady, F. Keynia, and H. Zareipour, "Short-term load forecast of microgrids by a new bilevel prediction strategy," IEEE Trans. Smart Grid, vol. 1, no. 3, pp. 286-294, Dec. 2010. [13] N. Charlton and C. Singleton, "A refined parametric model for short term load forecasting," Int J. Forecast, vol. 30, no. 2, pp. 364-368, Apr./Jun. 2014. [14] D. Fay and J. Ringwood, "On the influence of weather forecast errors in short-term load forecasting models," IEEE Trans. Power Syst, vol. 25, no. 3, pp. 1751-1758, Aug. 2010. [15] J. W. Taylor and R. Buizza, "Neural network load forecasting with weather ensemble predictions," IEEE Trans. Power Syst, vol. 17, no. 3, pp. 626-632, Aug. 2002. [16] T. Hong and P. Wang, "Fuzzy interaction regression for short term load forecasting," Fuzzy Optim. Decis. Making, vol. 13, no. 1, pp. 91-103, Mar. 2014. [17] D. Saez, F. Avila, D. Olivares, C. Canizares, and L. Marin, "Fuzzy prediction interval models for forecasting renewable resources and loads in microgrids," IEEE Trans. Smart Grid, vol. 6, no. 2, pp. 548-556, Mar. 2015. [18] Y. Semero, J. Zhang, and D. Zheng, "EMD-PSO-ANFIS-based hybrid approach for short-term load forcasting in microgrids," IET Generation, Transmission, and Distribution, vol. 14, no. 3, pp. 470-475, Feb. 2020. [19] P. E. McSharry, S. Bouwman, and G. Bloemhof, "Probabilistic forecasts of the magnitude and timing of peak electricity demand," IEEE Trans. Power Syst, vol. 20, no. 2, pp. 1166-1172, May 2005. [20] O. E. Dragomir, F. Dragomir, R. Gouriveau, and E. Minca, "Medium term load forecasting using ANFIS predictor," in Proc. 18th Mediterranean Conf. on Control and Automation, MED'10, pp. 23-25, Marrakech, Morocco, 23-25 Jun. 2010. [21] B. Akdemir and N. Cetinkaya, "Long-term load forecasting based on adaptive neural fuzzy," Energy Procedia, vol. 14, pp. 794-799, 2012. [22] B. Liu, J. Nowotarski, T. Hong, and R. Weron, "Probabilistic load forecasting via quantile regression averaging on sister forecasts," IEEE Trans. on Smart Grid, vol. 8, no. 2, pp. 730-737, Mar. 2017. [23] J. Peng, S. Gao, and A. Ding, "Study of the short-term electric load forecast based on ANFIS," in Proc. 32nd Youth Academic Annual Conf. of Chinese Association of Automation, YAC’17, pp. 832-836, Hefei, China, 19-21 May 2017. [24] I. Guler and E. D. Ubeyli, "Adaptive neuro-fuzzy inference system for classification of EEG signals using wavelet coefficients," J. of Neuroscience Methods, vol. 148, no. 2, pp. 113-121, 30 Oct. 2005. [25] W. Yang, K. Wang, and W. Zuo, "Neighborhood component feature selection for high-dimensional data," J. of Computers, vol. 7, no. 1, pp. 161-168, Jan. 2012. [26] R. Ross Jr, "Flat-plate photovoltaic array design optimization," in Proc. 14th Photovoltaic Specialists Conf., vol. 1, pp. 1126-1132, San Diego, CA, USA, 7-20 Jan. 1980. [27] A. S. B. M. Shah, H. Yokoyama, and N. Kakimoto, "High-precision forecasting model of solar irradiance based on grid point value data analysis for an efficient photovoltaic system," IEEE Trans. Sustainable Energy, vol. 6, no. 2, pp. 474-481, Apr. 2015. [28] N. Blair, et al., System Advisor Model, SAM 2014.1. 14: General Description, NREL Rep. No. TP-6A20-61019, Natl. Renew. Energy Lab. Golden, vol. 13, 2014. [29] Y. T. Weng and Y. Y. Hsu, "Reactive power control strategy for a wind farm with DFIG," J. of Renewable Energy, vol. 94, pp. 383-390, Aug. 2016. [30] J. Tian, C. Su, and Z. Chen, "Reactive power capability of the wind turbine with doubly fed induction generator," in Proc. IECON 39th Annual Conf. of the IEEE Industrial Electronics Society, pp. 5312-5317, Vienna, Austria, 10-13 Nov. 2013. [31] J. G. Slootweg, S. W. H. de Haan, H. Polinder, and W. L. Kling, "General model for representing variable speed wind turbines in power system dynamics simulations," IEEE Trans. on Power System, vol. 18, no. 1, pp. 144-151, Feb. 2003.OmidsharifiyanamajiddehghaniGhazanfarShahgholianS.M. MehdiMirtalaeiMasoudJabbari1092021778910.66224/ijece.28939.19.2.77http://ijece.org/fa/Article/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939http://ijece.org/fa/Article/Download/28939[1] G. Haghshenas, S. M. M. Mirtalaei, H. Mordmand, and G. Shahgholian, "High step-up boost-fly back converter with soft switching for photovoltaic applications," J. of Circuits, Systems, and Computers, vol. 28, no. 1, pp. 1-16, Jan. 2019. [2] ا. بابائی، ا. عباس‌نژاد، س. علیلو و م. صباحی، "تحلیل، طراحی و شبیه‌سازی یک مبدل dc/dc کاهنده با کلیدزنی تحت ولتاژ و جریان صفر،" نشریه کیفیت و بهره‌وری صنعت برق ایران، سال 4، شماره 2، صص. 62- 49، پاييز و زمستان 1394. [3] S. H. Mozafarpoor-Khoshrodi and G. Shahgholian, " Improvement of perturb and observe method for maximum power point tracking in wind energy conversion system using fuzzy controller," Energy Equipment and Systems, vol. 4, no. 2, pp. 111-122, Autumn 2016. [4] K. Khani and G. Shahgholian, "Analysis and optimization of frequency control in isolated microgrid with double-fed induction-generators based wind turbine," J. of International Council on Electrical Engineering, vol. 9, no. 1, pp. 24-37, Feb. 2019. [5] م. ر. بنائي و ح. اژدرفائقي بناب، "آنالیز عملکرد مبدل dc-dc کاهنده- افزاینده جدید با ضریب افزایندگی بالا برای کاربرد در سیستم خورشیدی،" نشریه مهندسی برق و مهندسی کامپیوتر ایران، الف- نشریه مهندسی برق، سال 15، شماره 3، صص. 184- 175، پاییز 1396. [6] ر. علی‌اکبری و م. دلشاد، "یک مبدل بسیار افزاینده کلیدزنی در جریان صفر جدید با المان کمکی کم،" روش‌های هوشمند در صنعت برق، سال 8، شماره 32، صص. 28- 21، زمستان 1396. [7] س. م. م. میرطلائی و ر. امانی نافچی، "مبدل DC-DC بسیار افزاینده بوست با سلف تزویج‌شده و تکنیک دیود- خازن،" نشریه روش‌های هوشمند در صنعت برق، سال 10، شماره 39، صص. 12- 3، پاییز 1398. [8] B. P. R. Baddipadiga, V. A. K. Prabhala, and M. Ferdowsi, "A family of high-voltage-gain DC-DC converters based on a generalized structure," IEEE Trans. on Power Electronics, vol. 33, no. 10, pp. 8399-8411, Oct. 2018. [9] N. Vazquez, L. Estrada, C. Hernandez, and E. Rodriguez, "The tapped-inductor boost converter," in Proc. of the Int. Symp. on Industrial Electronics, . pp. 538-543, Vigo, Spain, 4-7 Jun. 2007. [10] J. Yao, K. Li, K. Zheng, and A. Abramovitz, "On the equivalence of the switched inductor and the tapped inductor converters and its application to small signal modelling," Energies, vol. 12, Article No.: 4906, 19 pp., 2019. [11] Q. Zhao and F. C. Lee, "High performance coupled-inductor dc-dc converter," in Proc. of 18th Annual IEEE Applied Power Electronics Conf. and Exposition, pp. 109-113, Miami Beach, FL, USA, 9-13 Feb. 2003. [12] T. V. Nguyen, et al., "Self-powered high efficiency coupled inductor boost converter for photovoltaic energy conversion," Energy Procedia, vol. 36, pp. 650-656, 2013. [13] Q. Zhao and F. C. Lee, "High-efficiency, high step-up dc-dc converters," IEEE Trans. on Power Electronics, vol. 18, no. 1, pp. 65-73, Jan. 2003. [14] T. Wu, Y. Lai, J. Hung, and Y. Chen, "Boost converter with coupled inductors and buck-boost type of active clamp," IEEE Trans. on Industrial Electronics, vol. 55, no. 1, pp. 154-162, Jan. 2008. [15] D. M. Van de Sype, K. De Gusseme, W. R. Ryckaert, A. P. Van de Bossche, and J. A. Melkebeek, "A single switch buck-boost converter with a high conversion ratio," in Proc. European Conference on Power Electronics and Applications, pp. 1-10, Dresden, Germany, Sept. 2005. [16] W. Li and X. He, "Review of non-isolated high-step-up dc/dc converters in photovoltaic grid-connected applications," IEEE Trans. on Industrial Electronics, vol. 58, no. 4, pp. 1239-1250, Apr. 2011. [17] H. Liu, H. Hu, H. Wu, Y. Xing, and I. Batarseh, "Overview of high-step-up coupled-inductor boost converters," IEEE J. of Emerging and Selected Topics in Power Electronics, vol. 4, no. 2, pp. 689-704, Jun. 2016. [18] Y. Zhao, W. Li, and X. He, "Single-phase improved active clamp coupled-inductor-based converter with extended voltage doubler cell," IEEE Trans. on Power Electronics, vol. 27, no. 6, pp. 2869-2878, Jun. 2012. [19] B. Gu, J. Dominic, J. S. Lai, Z. Zhao, and C. Liu, "High boost ratio hybrid transformer DC-DC converter for photovoltaic module applications," in Proc. . of 18th Annual IEEE Applied Power Electronics Conf. and Exposition, pp. 598-606, Orlando, FL, USA, 5-9 Feb. 2012. [20] T. Liang, S. Chen, L. Yang, J. Chen, and A. Ioinovici, "Ultra-large gain step-up switched-capacitor dc-dc converter with coupled inductor for alternative sources of energy," IEEE Trans. on Circuits and Systems, vol. 59, no. 4, pp. 864-874, Apr. 2012. [21] R. Wai, C. Lin, R. Duan, and Y. Chang, "High-efficiency DC-DC converter with high voltage gain and reduced switch stress," IEEE Trans. on Industrial Electronics, vol. 54, no. 1, pp. 354-364, Feb. 2007. [22] K. Tseng, J. Lin, and C. Huang, "High step-up converter with three-winding coupled inductor for fuel cell energy source applications," IEEE Trans. on Power Electronics, vol. 30, no. 2, pp. 574-581, Feb. 2015. [23] J. W. Baek, M. H. Ryoo, T. J. Kim, D. W. Yoo, and J. S. Kim, "High boost converter using voltage multiplier," in Proc. 31st Annual Conf. of IEEE Industrial Electronics Society, 6 pp., Raleigh, NC, USA, 6-10 Nov. 2005. [24] T. J. Liang, S. M. Chen, L. S. Yang, J. F. Chen, and A. Ioinovici, "Ultra large gain step-up switched-capacitor DC-DC converter with coupled inductor for alternative sources of energy," IEEE Trans. on Circuit and System, vol. 59, no. 4, pp. 864-874, Apr. 2012. [25] D. R. Garth, W. J. Muldoon, G. C. Benson, and E. N. Costague, "Multi-phase, 2-kilowatt, high-voltage, regulated power supply," in Proc. of EEE Power Electronics Specialists Conf., pp. 110-116, Pasadena, CA, USA, 19-20 Apr. 1971. [26] M. T. Zhang, Y. Jiang, F. C. Lee, and M. M. Jovanovic, "Single-phase three-level boost power factor correction converter," in Proc. IEEE Applied Power Electronics Conference and Exposition , vol. 1, pp. 434-439, Dallas, TX, USA, 5-9 Mar. 2002. [27] K. I. Hwu and Y. T. Yau, "An interleaved ac-dc converter based on current tracking," IEEE Trans. on Industrial Electronics, vol. 56, no. 5, pp. 1456-1463, May 2009. [28] G. Franceschini, E. Lorenzani, M. Cavatorta, and A. Bellini, "3boost: a high-power three-phase step-up full-bridge converter for automotive applications," IEEE Trans. on Industrial Electronics, vol. 55, no. 1, pp. 173-183, Jan. 2008. [29] P. W. Lee, Y. S. Lee, D. K. W. Cheng, and X. C. Liu, "Steady-state analysis of an interleaved boost converter with coupled inductors," IEEE Trans. on Industrial Electronics, vol. 47, no. 4, pp. 787-795, Aug. 2000. [30] X. Huang, X. Wang, T. Nergaard, J. S. Lai, X. Zhu, and L. Xu, "Parasitic ringing and design issues of digitally controlled high-power interleaved boost converters," IEEE Trans. on Power Electronics, vol. 19, no. 5, pp. 1341-1352, Sep. 2004. [31] L. Huber and M. M. Jovanovic, "A design approach for server power supplies for networking applications," in Proc. of 15th Annual IEEE Applied Power Electronics Conf. and Expo., vol. 2, pp. 1163-1169, New Orleans, LA, USA, 6-10 Feb. 2000. [32] X. Feng, J. Liu, and F. C. Lee, "Impedance specifications for stable dc distributed power systems," IEEE Trans. on Power Electronics, vol. 17, no. 2, pp. 157-162, Mar. 2002. [33] T. F. Wu and T. H. Yu, "Unified approach to developing single-stage power converters," IEEE Trans. on Aerospace and Electronic Systems, vol. 34, no. 1, pp. 211-223, Jan. 1998. [34] B. R. Lin and J. J. Chen, "Analysis and implementation of a soft switching converter with high-voltage conversion ratio," IET-Power Electron, vol. 1, no. 3, pp. 386-394, Oct. 2008. [35] R. Suriyakulnaayudhya, "A high gain step-up fly boost converter for high voltage high power applications," in Proc. of the IEEE/EEEIC, vol. ???, pp. 1268-1272, Rome, Italy, Jun. 2015. [36] S. L. Brockveld and G. Waltrich, "Boost-flyback converter with interleaved input current and output voltage series connection," IET Power Electronics, vol. 11, no. 8, pp. 1463-1471, May 2018. [37] A. B. Shitole, S. Sathyan, H. Suryawanshi, M. G. G. Talapur, and P. Chaturvedi, "Soft-switched high voltage gain boost-integrated flyback converter interfaced single-phase grid-tied inverter for SPV integration," IEEE Trans. on Industry Applications, vol. 54, no. 1, pp. 482-493, Jan./Feb. 2018. [38] A. E. L. Costa and R. L. Andersen, "High-gain boost-boost-flyback converter for renewable energy sources applications," in Proc. of the IEEE 13th Brazilian Power Electronics Conf. and 1st Southern Power Electronics Conf., 6 pp., Fortaleza, Brazil, 29 Nov.-2 Dec. 2015. [39] س. م. م. میرطلائی و ر. جابری، "بررسی مبدل بوست- فلای‌بک بهره بالا در کاربرد سیستم‌های خورشیدی،" روش‌های هوشمند در صنعت برق، سال 9، شماره 34، صص. 28- 19، تابستان 1397. [40] V. T. Liu and L. J. Zhang, "Design of high efficiency boost-forward-flyback converters with high voltage gain," in Proc. of the IEEE Int. Conf. on Control & Automation, pp. 1061-1066, Taichung, Taiwan, 18-20 Jun. 2014. [41] A. M. S. S. Andrade, E. Mattos, and M. L. S. Martins, "High-efficiency boost-flyback converter with voltage multiplier cells for high voltage gain application," Electric Power Components and Systems, vol. 46, no. 1, pp. 104-111, 2018. [42] A. Affam, Y. Buswig, A. H. Othman, N. B. Julai, and O. Qays, "A review of multiple input dc-dc converter topologies linked with hybrid electric vehicles and renewable energy systems," Renewable and Sustainable Energy Reviews, vol. 135, Article No.: 110186, 23 pp., Jan. 2021. [43] M. Jabbari and M. S. Dorcheh, "Resonant multi-input/multi-output/bidirectional ZCS step-down dc-dc converter with systematic synthesis for point-to-point power routing," IEEE Trans. on Power Electronics, vol. 33, no. 7, pp. 6024-6032, Jul. 2018. [44] M. Veerachary and P. Kumar, "Analysis and design of quasi-z-source equivalent dc-dc boost converters," IEEE Trans. on Industry Applications, vol. 56, no. 6, pp. 6642-6656, Nov./Dec. 2020. [45] S. Hasanpour, Y. Siwakoti, and F. Blaabjerg, "Hybrid cascaded high step-up dc/dc converter with continuous input current for renewable energy applications," IET Power Electronics, vol. 13, no. 15, pp. 3487-3495, Nov. 2020. [46] A. Alzahrani, P. Shamsi, and M. Ferdowsi, "A novel non-isolated high-gain dc-dc boost converter," in Proc. of North American Power Symp., 6 pp., Morgantown, WV, USA, 17-19 Sept. 2017. [47] M. Premkumar, et al., "A novel non-isolated high step-up DC-DC boost converter using single switch for renewable energy systems," Electrical Engineering, vol. 102, no. ???, pp. 811-829, Jun. 2020. [48] N. H. Pour and K. Varesi, "A new non-isolated high gain DC-DC converter suitable for renewable energies," in Proc. of the 10th Int. Power Electronics, Drive Systems and Technologies Conf., pp. 747-751, Shiraz, Iran, 12-14 Feb. 2019. [49] M. Hanifehpour, et al., "No-isolated high gain dc/dc converter with low input current ripple suitable for renewable applications," Electric Power Components and Systems, vol. 48, no. 11, pp. 1171-1184, 2020. [50] M. Eydi, S. H. Hosseini, and R. Ghazi, "A new high gain DC-DC boost converter with continuous input and output currents," in Proc. of the the 10th Int. Power Electronics, Drive Systems and Technologies Conf.,, pp. 224-229, Shiraz, Iran, 12-14 Feb. 2019. [51] J. Loranca-Coutino, et al., "High gain boost converter with reduced voltage in capacitors for fuel-cells energy generation systems," Electronics, vol. 9, no. 11, Article Number: 1480, 20 pp., Nov. 2020. [52] F. L. Tofoli, D. C. Pereira, W. J. Paula, and D. S. O. Junior, "Survey on non-isolated high-voltage step-up dc-dc topologies based on the boost converter," IET Power Electronics, vol. 8, no. 10, pp. 2044-2057, Oct. 2015. [53] W. Yu, et al., "High efficiency converter with charge pump and coupled inductor for wide input photovoltaic ac module applications," in Proc. IEEE Energy Conversion Congress and Expo., pp. 3895-3900, San Jose, CA, USA, 20-24 Sept. 2009. [54] R. J. Wai and R. Y. Duan, "High step-up converter with coupled-inductor," IEEE Trans. on Power Electronics, vol. 20, no. 5, pp. 1025-1035, Sept. 2005.RezaInanlouOmidShoaei109202111912610.66224/ijece.28953.19.2.119http://ijece.org/fa/Article/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953http://ijece.org/fa/Article/Download/28953[1] L. Wang, et al., "A wireless biomedical signal interface system-on-chip for body sensor networks," IEEE Trans. Biomed. Circuits Syst., vol. 4, no. 2, pp. 112-117, Apr. 2010. [2] A. Urso, et al., "A switched-capacitor DC-DC converter powering an LC oscillator to achieve 85% system peak power efficiency and -65 dBc spurious tones," IEEE Trans. on Circ. and Sys. I: Regular Papers, vol. 67, no. 11, pp. 3764-3777, Nov. 2020. [3] C. Tao and A. A. Fayed, "A low-noise PFM-controlled buck converter for low-power applications," IEEE Trans. on Circ. and Sys. I: Regular Papers, vol. 59, no. 12, pp. 3071-3080, Dec. 2012. [4] J. H. Chen, P. J. Liu, and Y. J. E. Chen, "A spurious emission reduction technique for power amplifiers using frequency hopping DC-DC converters," in Proc. IEEE Radio Freq. Integr. Circuits Symp., pp. 145-148, Boston, MA, USA, 7-9 Jun. 2009. [5] M. W. Kim and J. J. Kim, "A PWM/PFM dual-mode DC-DC buck converter with load-dependent efficiency-controllable scheme for multi-purpose IoT applications," Energies, vol. 14, pp. 1-14, Feb. 2021. [6] R. Inanlou, O. Shoaei, and M. Tamaddon, "An asynchronous pulse width modulator for DC-DC buck converter," International J. of Circuit Theory and Applications, vol. 48, no. 2, pp. 231-253, Feb. 2020. [7] -, TPS7A49xx Series Data Sheet, Texas Instruments Incorp., 2010. [Online]. Available: www.ti.com › Power Management › Linear Regulator (LDO). [8] A. V. Oppenheim, A. S. Willsky, and I. T. Young, Signals and Systems, Prentice Hall, NJ, 1983. [9] H. S. Black, Modulation Theory, D. Van Nostrand Company, NY, 1953. [10] W. A. Burklandn, C. Tao, and A. A. Fayed, "Output switching noise spectral analysis and modeling in buck regulators," Microelectronics J., vol. 44, no. 5, pp. 373-381, Mar. 2013. [11] T. Hegarty, An Overview of Radiated EMI Specifications for Power Supplies, Texas Instruments, Jun. 2018. Available: www.ti.com/lit/wp/slyy142/slyy142.pdf [12] Y. Choi, W. Tak, Y. Yoon, J. Roh, S. Kwon, and J. Koh, "A 0.018% THD+N, 88-dB PSRR PWM Class-D amplifier for direct battery hookup," IEEE J. Solid-State Circ., vol. 47, no. 2, pp. 454-463, Feb. 2012. [13] S. K. Dunlap and T. S. Fiez, "A noise-shaped switching power supply using a delta-sigma modulator," IEEE TCAS-I, vol. 51, no. 6, pp. 1051-1061, Jun. 2004. [14] Y. S. Hwang, et al., "A low-EMI continuous-time delta-sigma-modulation buck converter with transient response eruption techniques," IEEE Trans. on Ind. Electron., vol. 67, no. 8, pp. 6854-6863, Aug. 2020. [15] J. J. Chen, et al., "A low-electromagnetic-interference buck converter with continuous-time delta-sigma-modulation and burst-mode techniques," IEEE Trans. on Ind. Electron., vol. 65, no. 9, pp. 6860-6869, Sep. 2018. [16] J. J. Chen, Y. S. Hwang, J. H. Yu, Y. T. Ku, and C. C. Yu, "A low-EMI buck converter suitable for wireless sensor networks with spur-reduction techniques," IEEE Sensors J., vol. 16, no. 8, pp. 2588-2597, Apr. 2016. [17] Y. S. Hwang, J. J. Chen, W. J. Hou, P. H. Liao, and Y. T. Ku, "A 10 μs transient recovery time low-EMI DC-DC buck converter with Δ–Ʃ modulator," IEEE Trans. Very Large Scale Integr. (VLSI) Sys., vol. 24, no.9, pp. 2983-2992, Mar. 2016. [18] W. H. Yang, et al., "An enhanced-security buck DC-DC converter with true-random-number-based pseudo hysteresis controller for Internet-of-Everything (IoE) devices," in Proc. IEEE Int. Solid-State Circuits Conf., ISSCC'18, pp. 126-128, Feb. 2018. [19] M. Nashed and A. A. Fayed, "A current-mode hysteretic buck converter with spur-free control for variable switching noise mitigation," IEEE Trans. Power Electronics, vol. 33, no. 1, pp. 650-664, Jan. 2018. [20] L. Corradini, A. Bjeletic, R. Zane, and D. Maksimovic, "Fully digital hysteretic modulator for DC-DC switching converters," IEEE Trans. on Power Electronics, vol. 26, no. 10, pp. 2969-2979, Oct. 2011. [21] M. Hoyerby and M. Andersen, "Carrier distortion in hysteretic self-oscillating class-D audio power amplifiers: analysis and optimization," IEEE Trans. Power Electron., vol. 24, no. 3, pp. 714-729, Mar. 2009. [22] M. Tamaddon and M. Yavari, "An oscillatory noise‐shaped quantizer for time‐based continuous‐time sigma‐delta modulators," International J. of Circuit Theory and Applications, vol. 46, no. 3, pp. 384-400, Mar. 2018. [23] W. Li, Y. Orino, S. Hirata, and M. K. Kurosawa, "Design of a self-oscillating PWM signal generator with a double integration loop," IEEE Trans. on Circ. and Sys. I (TCAS_I): Regular Papers, vol. 60, no. 8, pp. 2064-2073, Feb. 2013. [24] H. G. Li, S. D. Gong, J. W. Liu, and D. L. Su, "CMOS-based chaotic PWM generator for EMI reduction," IEEE Trans. Electromagn. Compat., vol. 59, no. 4, pp. 1224-1231, Aug. 2017. [25] M. L. Chiu, T. H. Yang, and T. H. Lin, "A high accuracy constant-on-time buck converter with spur-free on-time generator," in Proc. IEEE Int. Symp. on Circuits and Systems, ISCAS'19, 4 pp., Sapporo, Japan, 26-29 May 2019. [26] C. Tao and A. A. Fayed, "A buck converter with reduced output spurs using asynchronous frequency hopping," IEEE Trans. on Circ. and Sys. II: Express Briefs, vol. 58, no. 11, pp. 709-713, Nov. 2011. [27] H. Li, J. Shang, B. Zhang, X. Zhao, N. Tan, and C. Liu, "Stability analysis with considering the transition interval for PWM DC-DC converters based on describing function method," IEEE Access, vol. 6, pp. 48113-48124, Jul. 2018. OmidAbdoliE.GholipourR.Hooshmand109202113514110.66224/ijece.28966.19.2.135http://ijece.org/fa/Article/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966http://ijece.org/fa/Article/Download/28966[1] I. Series, Microgrids and Active Distribution Networks, the Institution of Engineering and Technology, 2009. [2] R. Teodorescu, M. Liserre, and P. Rodriguez, Grid Converters for Photovoltaic and Wind Power Systems, John Wiley & Sons, 2011. [3] C. Y. Tang, Y. T. Chen, and Y. M. Chen, "PV power system with multi-mode operation and low-voltage ride-through capability," IEEE Trans. on Industrial Electronics, vol. 62, no. 12, pp. 7524-7533, Dec. 2015. [4] E. Afshari, et al., "Control strategy for three-phase grid-connected PV inverters enabling current limitation under unbalanced faults," IEEE Trans. on Industrial Electronics, vol. 64, no. 11, pp. 8908-8918, Nov. 2017. [5] L. Djilali, E. N. Sanchez, F. Ornelas-Tellez, A. Avalos, and M. Belkheiri, "Improving microgrid low-voltage ride-through capacity using neural control," IEEE Systems J., vol. 14, no. 2, pp. 2825-2836, Jun. 2019. [6] A. Mojallal and S. Lotfifard, "Enhancement of grid connected PV arrays fault ride through and post fault recovery performance," IEEE Trans. on Smart Grid, vol. 10, no. 1, pp. 546-555, Jan. 2017. [7] D. Eltigani and S. Masri, "Challenges of integrating renewable energy sources to smart grids: a review," Renewable and Sustainable Energy Reviews, vol. 52, pp. 770-780, Dec. 2015. [8] H. Tian, F. Gao, C. Ma, G. He, and G. Li, "A review of low voltage ride-through techniques for photovoltaic generation systems," in Proc. IEEE Energy Conversion Congress and Exposition, ECCE’14, pp. 1566-1572, Pittsburgh, PA, USA, 14-18 Sept. 2014. [9] A. Q. Al-Shetwi, M. Z. Sujod, F. Blaabjerg, and Y. Yang, "Fault ride-through control of grid-connected photovoltaic power plants: a review," Solar Energy, vol. 180, pp. 340-350, Mar. 2019. [10] L. Niu, X. Wang, L. Wu, F. Yan, and M. Xu, "Review of low voltage ride-through technology of doubly-fed induction generator," The J. of Engineering, vol. 2019, no. 16, pp. 3106-3108, Mar. 2019. [11] O. P. Mahela, N. Gupta, M. Khosravy, and N. Patel, "Comprehensive overview of low voltage ride through methods of grid integrated wind generator," IEEE Access, vol. 7, pp. 99299-99326, 2019. [12] H. Shin, J. Jung, S. Oh, K. Hur, K. Iba, and B. Lee, "Evaluating the influence of momentary cessation mode in inverter-based distributed generators on power system transient stability," IEEE Trans. on Power Systems, vol. 35, no. 2, pp. 1618-1626, Mar. 2019. [13] S. Mortazavian and Y. A. R. I. Mohamed, "Dynamic analysis and improved lvrt performance of multiple dg units equipped with grid-support functions under unbalanced faults and weak grid conditions," IEEE Trans. on Power Electronics, vol. 33, no. 10, pp. 9017-9032, Oct. 2017. [14] X. Wang, J. Yao, J. Pei, P. Sun, H. Zhang, and R. Liu, "Analysis and damping control of small-signal oscillations for VSC connected to weak AC grid during LVRT," IEEE Trans. on Energy Conversion, vol. 34, no. 3, pp. 1667-1676, Sept. 2019. [15] Z. Yang, R. Ma, S. Cheng, and M. Zhan, "Nonlinear modeling and analysis of grid-connected voltage source converters under voltage dips," IEEE J. of Emerging and Selected Topics in Power Electronics, vol. 8, no. 4, pp. 3281-3292, Dec. 2020. [16] A. Movahedi, A. H. Niasar, and G. B. Gharehpetian, "LVRT improvement and transient stability enhancement of power systems based on renewable energy resources using the coordination of SSSC and PSSs controllers," IET Renewable Power Generation, vol. 13, no. 11, pp. 1849-1860, Aug. 2019. [17] D. Pan, X. Wang, F. Liu, and R. Shi, "Transient stability of voltage-source converters with grid-forming control: a design-oriented study," IEEE J. of Emerging and Selected Topics in Power Electronics, vol. 8, no. 2, pp. 1019-1033, Jun. 2019. [18] D. Pan, X. Wang, F. Liu, and R. Shi, "Transient stability analysis of droop-controlled grid-connected converters with inertia emulating low-pass filters," in Proc. IEEE Energy Conversion Congress and Exposition, ECCE’19, pp. 34-40, Baltimore, MD, USA, 29 Sept.-3 Oct. 2019. [19] L. Huang, H. Xin, Z. Wang, L. Zhang, K. Wu, and J. Hu, "Transient stability analysis and control design of droop-controlled voltage source converters considering current limitation," IEEE Trans. on Smart Grid, vol. 10, no. 1, pp. 578-591, Jan. 2017. [20] M. G. Taul, X. Wang, P. Davari, and F. Blaabjerg, "An overview of assessment methods for synchronization stability of grid-connected converters under severe symmetrical grid faults," IEEE Trans. on Power Electronics, vol. 34, no. 10, pp. 9655-9670, Oct. 2019. [21] X. He, H. Geng, R. Li, and B. C. Pal, "Transient stability analysis and enhancement of renewable energy conversion system during LVRT," IEEE Trans. on Sustainable Energy, vol. 11, no. 3, pp. 1612-1623, Jul. 2020. [22] J. Pei, et al., "Characteristic analysis and risk assessment for voltage-frequency coupled transient instability of large-scale grid-connected renewable energy plants during LVRT," IEEE Trans. on Industrial Electronics, vol. 67, no. 7, pp. 5515-5530, Jul. 2020. [23] P. Sun, et al., "Virtual capacitance control for improving dynamic stability of the DFIG-based wind turbines during a symmetrical fault in a weak AC grid," IEEE Trans. on Industrial Electronics, vol. 68, no. 1, pp. 333-346, Jan. 2021. [24] J. A. Suul, S. D'Arco, P. Rodriguez, and M. Molinas, "Impedance-compensated grid synchronisation for extending the stability range of weak grids with voltage source converters," IET Generation, Transmission & Distribution, vol. 10, no. 6, pp. 1315-1326, Apr. 2016. [25] B. Weise, "Impact of K-factor and active current reduction during fault-ride-through of generating units connected via voltage-sourced converters on power system stability," IET Renewable Power Generation, vol. 9, no. 1, pp. 25-36, Jan. 2015.NimarajabiRamazanHavangi1092021909810.66224/ijece.28984.19.2.90http://ijece.org/fa/Article/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984http://ijece.org/fa/Article/Download/28984[1] A. Baratta, I. Corbi, O. Corbi, R. Carneiro Barros, and R. Bairrao, "Shaking table experimental researches aimed at the protection of structures subject to dynamic loading," The Open Construction and Building Technology J., vol. 6, pp. 336-360, 2012. [2] X. Yang, H. Hongxing, and H. Junwei, "Three state controller design of shaking table in active structural control system," in Proc. IEEE Int. Conf. on Control and Automation, pp. 88-93, Guangzhou, China, 30 May-1 Jun. 2007. [3] D. J. Lee, et al., "The tracking control of uni-axial servo-hydraulic shaking table system using time delay control," in Proc. IEEE SICE-ICASE In. Joint Conf., , pp. 29-32, Busan, South Korea, 18-21 Oct. 2006. [4] K. Seki, M. Iwasaki, M. Kawafuku, H. Hirai, and K. Yasuda, "Adaptive compensation for reaction force with frequency variation in shaking table systems," IEEE Trans. on Industrial Electronics, vol. 56, no. 10, pp. 3864-3871, Oct. 2009. [5] ا. صادقی، ج. کریمی و س. ح. ساداتی، "طراحی قانون هدایت مقاوم سه‌بعدی ربات پرنده به روش فازی - مد لغزشی،" مجله مهندسی مکانیک شریف، دوره 33.3، شماره 2، صص. 25-13، پاییز و زمستان 1396. [6] س. شکی و م. ر. ذاکرزاده، "مدل¬سازی و کنترل عملگر آلیاژ حافظه¬دار با روش مد لغزشی فازی،" مجله مهندسی مکانیک مدرس، دوره 16، شماره 7، صص. 25-13، مهر 1395. [7] A. S. Oleg and V. M. Andrei, "Adaptive estimation algorithms and their applications to measurement data processing," in Proc. IEEE Conf. of Russian Young Researchers in Electrical and Electronic Engineering, EIConRus’19, pp. 3-8, Saint Petersburg and Moscow, Russia, 28-31 Jan. 2019. [8] Y. Huo, Z. Cai, W. Gong, and Q. Liu, "A new adaptive Kalman filter by combining evolutionary algorithm and fuzzy inference system," in Proc. IEEE Congress on Evolutionary Computation, CEC’14, pp. 2893-2900, Beijing, China, 6-11 Jul. 2014. [9] B. Feng, M. Fu, H. Ma, Y. Xia, and B. Wang, "Kalman filter with recursive covariance estimation-sequentially estimating process noise covariance," IEEE Trans. on Industrial Electronics, vol. 61, no. 11, pp. 6253-6263, Nov. 2014. [10] S. Sarkka and J. Hartikainen, "Non-linear noise adaptive Kalman filtering via variational Bayes," in Proc. IEEE Int. Workshop on Machine Learning for Signal Processing, MLSP’16, 6 pp., Southampton, UK, 22-25 Sept. 2016. [11] W. Liu, Y. Liu, and R. Bucknall, "A robust localization method for unmanned surface vehicle (USV) navigation using fuzzy adaptive Kalman filtering," IEEE Access, vol. 7, pp. 46071-46083, 2019. [12] A. Assad, W. Khalaf, and I. Chouaib, "Novel adaptive fuzzy extended Kalman filter for attitude estimation in GPS-denied environment, " Gyroscopy and Navigation, vol. 10, no. 3, pp. 131-146, 2019. [13] M. Tarnik and J. Murgas, "Model reference adaptive control of permanent magnet synchronous motor," J. of Electrical Engineering, vol. 62, no. 3, pp. 117-125, May 2011. [14] S. Yu, Y. Feng, and X. Yang, "Extended state observer-based fractional order sliding-mode control of piezoelectric actuators," Proc. of the Institution of Mechanical Engineers, Part I: J. of Systems and Control Engineering, Article No.: 0959651820934351, 2020. [15] X. Yang, P. Wei, Y. Zhang, X. Liu, and L. Yang, "Disturbance observer based on biologically inspired integral sliding mode control for trajectory tracking of mobile robots," IEEE Access, vol. 7, pp. 48382-48391, 2019. [16] K. S. Mawonou, A. Eddahech, D. Dumur, D. Beauvois, and E. Godoy, "Improved state of charge estimation for Li-ion batteries using fractional order extended Kalman filter," J. of Power Sources, vol. 435, Article No.: 226710, 30 Sept. 2019. [17] ا. صیادی، و م. ت. ثابت، "دینامیک و کنترل مجموعه ربات های غیر هولونومیک به منظور شرکت در عملیات شکار جمعی در سطوح غیرمستوی،" مجله مهندسی مکانیک شریف، دوره 30، شماره 1، صص. 37-15، پاییز و زمستان 1393. [18] L. Jiang and H. Zhang, "Redundant measurement-based second order mutual difference adaptive Kalman filter," Automatica, vol. 100, no. 3, pp. 396-402, Feb. 2019. [19] A. Mehrjouyan and A. Alfi, "Robust adaptive unscented Kalman filter for bearings-only tracking in three dimensional case," Applied Ocean Research, vol. 87, pp. 223-232, Jun. 2019. [20] N. Rajabi, A. H. Abolmasoumi, and M. Soleymani, "Sliding mode trajectory tracking control of a ball‐screw‐driven shake table based on online state estimations using EKF/UKF," Structural Control and Health Monitoring, vol. 25, no. 4, Article No.: e2133, Apr. 2018. [21] Pacific Earthquake Engineering, Earthquake and Station Details. Retrieved from http://www.peer.berkeley.edu.Mohammad KazemAnvarifard109202110911810.66224/ijece.29027.19.2.109http://ijece.org/fa/Article/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027http://ijece.org/fa/Article/Download/29027[1] M. K. Anvarifard and A. A. Orouji, "Voltage difference engineering in SOI MOSFETs: a novel side gate device with improved electrical performance," Materials Science in Semiconductor Processing, vol. 6, no. 1, pp. 1672-1678, Dec. 2013. [2] M. Rahimian, A. A. Orouji, and A. H. Aminbeidokhti, "A novel deep submicron SiGe-on-insulator (SGOI) MOSFET with modified channel band energy for electrical performance improvement," Current Applied Physics, vol. 13, no. 4, pp. 779-784, Jun. 2013. [3] M. Mehrad, "Controlling floating body effect in high temperatures: L-shape SiGe region in nano-scale MOSFET," Superlattices and Microstructures, vol. 85pp. 573-580, Sep. 2015. [4] A. A. Orouji and M. Jagadesh Kumar, "A new symmetrical double gate nanoscale MOSFET with asymmetrical side gates for electrically induced source/drain," Microelectronic Engineering, vol. 83, no. 3, pp. 409-414, Mar. 2006. [5] س. کلانتری و م. وادی‌زاده، "کاهش جریان خاموشی در ترانزیستور اثر میدان بدون پیوند دوگیتی نانومتری با استفاده از مهندسی آلایش میانه کانال،" نشریه مهندسی برق و مهندسی کامپیوتر ایران، الف- مهندسی برق، جلد 16، شماره 1، صص. 42-37، بهار 1397. [6] م. وادی‌زاده، س. ص. قریشی و م. فلاح‌نژاد، "استفاده از گیت کمکی برای بهبود مشخصات الکتریکی ترانزیستور اثر میدان بدون پیوند سیلیکون بر روی عایق،" نشریه مهندسی برق و مهندسی کامپیوتر ایران، الف- مهندسی برق، جلد 18، شماره 1، صص. 72-67، بهار 1399. [7] س. م. رضوی، س. ح. ظهیری و س. ا. حسینی، "بررسی مشخصه‌های الکتریکی AlGaN/GaN-HEMT با واردکردن لایه P در لایه سد در دو سمت سورس و درین،" نشریه مهندسی برق و مهندسی کامپیوتر ایران، الف- مهندسی برق، جلد 15، شماره 3، صص. 222-217، پاییز 1396. [8] Z. Ramezani and A. A. Orouji, "Investigation of veritcal graded channel doping in nanoscale fully-depleted SOI-MOSFET," Superlattices and Microstructures, vol. 98, pp. 359-370, Oct. 2016. [9] M. Rahimian and A. A. Orouji, "Investigation of the electrical and thermal performance of SOI MOSFETs with modified channel engineering," Materials Science in Semiconductor Processing, vol. 16, no. 5, pp. 1248-1256, Oct. 2013. [10] J. P. Colinge, et al., "Junctionless nanowire transistor (JNT): properties and design guidelines," Solid-State Electronics, vol. 65/66, pp. 33-37, Nov./Dec. 2011. [11] R. K. Baruah and R. P. Paily, "A dual-material gate junctionless transistor with high-k spacer for enhanced analog performance," IEEE Trans. on Electron Devices, vol. 61, no. 1, pp. 123-128, Jan. 2014. [12] X. Jin, M. Wu, X. Liu, R. Chuai, H. I. Kwon, J. H. Lee, and J. H. Lee, "A novel high performance junctionless FETs with saddle-gate," J. of Computational Electronics, vol. 14, no. 3, pp. 661-668, May 2015. [13] C. W. Lee, I. Ferain, A. Afzalian, R. Yan, N. Dehdashti Akhavan, P. Razavi, and J. P. Colinge, "Performance estimation of junctionless multigate transistors," Solid-State Electronics, vol. 54, no. 2, pp. 97-103, Feb. 2010. [14] Y. Song, et al., "III-V junctionless gate-all-around nanowire MOSFETs for high linearity low power applications," IEEE Electron Device Letters, vol. 35, no. 3, pp. 324-326, Mar. 2014. [15] S. Min Lee, H. Jun Jang, and J. T. Park, "Impact of back gate biases on hot carrier effects in multiple gate junctionless transistors," Microelectronics Reliability, vol. 53, no. 9-11, pp. 1329-1332, Nov. 2013. [16] J. P. Colinge, C. W. Lee, A. Afzalian, N. D. Akhavan, R. Yan, I. Ferain, P. Razavi, B. O'Neill, A. Blake, M. White, A. M. Kelleher, B. McCarthy, and R. Murphy, "Nanowire transistors without junctions," Nature Nanotechnology, vol. 5, no. 3, pp. 225-229, Mar. 2010. [17] S. Gundapaneni, S. Ganguly, and A. Kottantharayil, "Bulk planar junctionless transistor (BPJLT): an attractive device alternative for scaling," IEEE Electron Device Letters, vol. 32, no. 3, pp. 261-263, Mar. 2011. [18] R. Yan, A. Kranti, I. Ferain, C. W. Lee, R. Yu, N. Dehdashti, P. Razavi, and J. P. Colinge, "Investigation of high-performance sub-50 nm junctionless nanowire transistors," Microelectronics Reliability, vol. 51, no. 7, pp. 1166-1171, Jul. 2011. [19] M. Rahimian and M. Fathipour, "Improvement of electrical performance in junctionless nanowire TFET using hetero-gate-dielectric," Materials Science in Semiconductor Processing, vol. 63, pp. 142-152, Jun. 2017. [20] M. Rahimian and M. Fathipour, "Junctionless nanowire TFET with built-in N-P-N bipolar action: physics and operational principle," J. of Applied Physics, vol. 120, Article No.: 225702, 2016. [21] SILVACO International, ATLAS User's Manual: 2-D Device Simulator, Santa Clara, CA, USA, 2016. [22] W. B. Joyce and R. W. Dixon, "Analytic approximation for the fermi energy of an ideal fermi gas," Appl. Phys Lettvol. 31, no. 5, pp. 354-356, 1978. [23] S. Selberherr, Analysis and Simulation of Semiconductor Devices, Wien, New York: Springer-Verlag, 1984. [24] Z. Yu and R. W. Dutton, SEDAN III-A Generalized Electronic Material Device Analysis Program, Stanford Electronics Laboratory Technical Report, Stanford University, Jul. 1985. [25] M. K. Anvarifard and A. A. Orouji, "Evidence for enhanced reliability in a novel nanoscale partially-depleted SOI MOSFET," IEEE Trans. on Device and Materials Reliability, vol. 15, no. 4, pp. 536-542, Dec. 2015.AhmadBagheriH.Iman-Eini109202112713410.66224/ijece.29129.19.2.127http://ijece.org/fa/Article/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129http://ijece.org/fa/Article/Download/29129[1] S. Debnath, J. Qin, B. Bahrani, M. Saeedifard, and P. Barbosa, "Operation, control, and applications of the modular multilevel converter: a review," IEEE Trans. Power Electron., vol. 30, no. 1, pp. 37-53, Jan. 2015. [2] A. Dekka, B. Wu, R. L. Fuentes, M. Perez, and N. R. Zargari, "Evolution of topologies, modeling, control schemes, and applications of modular multilevel converters," IEEE J. Emerg. Sel. Top. Power Electron., vol. 5, no. 4, pp. 1631-1656, Dec. 2017. [3] F. Deng, Y. Lu, C. Liu, Q. Heng, Q. Yu, and J. Zhao, "Overview on submodule topologies, modeling, modulation, control schemes, fault diagnosis, and tolerant control strategies of modular multilevel converters," Chin. J. Elect. Eng., vol. 6, no. 1, pp. 1-21, Mar. 2020. [4] B. Li, S. Zhou, D. Xu, S. J. Finney, and B. W. Williams, "A hybrid modular multilevel converter for medium-voltage variable-speed motor drives," IEEE Trans. Power Electron., vol. 32, no. 6, pp. 4619-4630, Jun. 2016. [5] Y. S. Kumar and G. Poddar, "Control of medium-voltage AC motor drive for wide speed range using modular multilevel converter," IEEE Trans. Ind. Electron., vol. 64, no. 4, pp. 2742-2749, Apr. 2016. [6] M. S. Diab, A. Massoud, S. Ahmed, and B. Williams, "A modular multilevel converter with ripple-power decoupling channels for three-phase MV adjustable-speed drives," IEEE Trans. on Power Electronics, vol. 34, no. 5, pp. 4048-4063, May 2019.ُ [7] A. Marzoughi, R. Burgos, D. Boroyevich, and Y. Xue, "Design and comparison of cascaded h-bridge modular multilevel converter and 5-l active neutral point clamped topologies for motor drive application," IEEE Trans. Ind. Appl., vol. 54, no. 2, pp. 1404-1413, Mar./ Apr. 2018. [8] A. Antonopoulos, L. Angquist, S. Norrga, K. Ilves, L. Harnefors, and H. P. Nee, "Modular multilevel converter ac motor drives with constant torque from zero to nominal speed," IEEE Trans. Ind. Appl., vol. 50, no. 3, pp. 1982-1993, May/Jun. 20140 [9] S. Debnath, J. Qin, and M. Saeedifard, "Control and stability analysis of modular multilevel converter under low-frequency operation," IEEE Trans. Ind. Electron., vol. 62, no. 9, pp. 5329-5339, Sept. 2015. [10] B. Li, et al., "An improved circulating current injection method for modular multilevel converters in variable-speed drives," IEEE Trans. Ind. Electron., vol. 63, no. 11, pp. 7215-7225, Nov. 2016. [11] S. Sau and B. G. Fernandes, "Modular multilevel converter based variable speed drive with reduced capacitor ripple voltage," IEEE Trans. Ind. Electron., vol. 66, no. 5, pp. 3412-3421, May 2019. [12] J. Kolb, F. Kammerer, M. Gommeringer, and M. Braun, "Cascaded control system of the modular multilevel converter for feeding variable-speed drives," IEEE Trans. Power Electron., vol. 30, no. 1, pp. 349-357, Jan. 2015. [13] B. Wu and M. Narimani, High-Power Converters and AC Drives, John Wiley & Sons, 2017. [14] S. Du, B. Wu, and N. R. Zargari, "Common-mode voltage elimination for variable-speed motor drive based on flying-capacitor modular multilevel converter," IEEE Trans. Power Electron., vol. 33, no. 7, pp. 5621-5628, Jul. 2018. [15] S. Du, B. Wu, and N. Zargari, "Common-mode voltage minimization for grid-tied modular multilevel converter," IEEE Trans. on Ind. Electron, vol. 66, no. 10, pp. 7480-7487, Jul. 2018. [16] M. Huang, J. Zou, X. Ma, Y. Li, and M. Han, "Modified modular multilevel converter to reduce submodule capacitor voltage ripples without common-mode voltage injected," IEEE Trans. Ind. Electron., vol. 66, no. 3, pp. 2236-2246, Mar. 2019. [17] S. Du, B. Wu, K. Tian, N. R. Zargari, and Z. Cheng, "An active cross-connected modular multilevel converter (AC-MMC) for a medium-voltage motor drive," IEEE Trans. Ind. Electron., vol. 63, no. 8, pp. 4707-4717, Aug. 2016. [18] S. Du, B. Wu, and N. R. Zargari, "A star-channel modular multilevel converter for zero/low-fundamental-frequency operation without injecting common-mode voltage," IEEE Trans. Power Electron., vol. 33, no. 4, pp. 2857-2865, Apr. 2018. [19] S. Du, B. Wu, and N. R. Zargari, "A delta-channel modular multilevel converter for zero/low-fundamental-frequency operation," IEEE Trans. Ind. Electron., vol. 66, no. 3, pp. 2227-2235, Mar. 2019. [20] S. Du, B. Wu, and N. Zargari, "Delta-channel modular multilevel converter for a variable-speed motor drive application," IEEE Trans. Ind. Electron., vol. 65, no. 8, pp. 6131-6139, Aug. 2018. [21] S. Du, B. Wu, N. R. Zargari, and Z. Cheng, "A flying-capacitor modular multilevel converter for medium-voltage motor drive," IEEE Trans. Power Electron., vol. 32, no. 3, pp. 2081-2089, Mar. 2016. [22] S. Du, A. Dekka, B. Wu, and N. Zargari, Modular Multilevel Converters: Analysis, Control, and Applications, John Wiley & Sons, 2017. [23] S. Du, B. Wu, and N. R. Zargari, "Current stress reduction for flying-capacitor modular multilevel converter," IEEE Trans. Power Electron., vol. 34, no. 1, pp. 184-191, Jan. 2019. [24] D. Dung Le and D. C. Lee, "Reduction of half-arm current stresses and flying-capacitor voltage ripples of flying-capacitor MMCs," Access IEEE, vol. 8, pp. 180076-180086, 2020.