Journal of Engineering and Applied Sciences
Year:
2020
Volume:
15
Issue:
1
Page No.
171 - 179
References
Adzic, E., Z. Ivanovic, M. Adzic and V. Katic, 2009. Maximum power search in wind turbine based on fuzzy logic control. Acta Polytech. Hungarica, 6: 131-149.
Direct Link | Blaabjerg, F., M. Liserre and K. Ma, 2011. Power electronics converters for wind turbine systems. IEEE. Trans. Ind. Appl., 48: 708-719.
CrossRef | Direct Link | Blaabjerg, F., Z. Chen and S.B. Kjaer, 2004. Power electronics as efficient interface in dispersed power generation systems. IEEE Trans. Power Electron., 19: 1184-1194.
CrossRef | Carrasco, J.M., L.G. Franquelo, J.T. Bialasiewicz, E. Galvan and R.P. Guisado
et al., 2006. Power-electronic systems for the grid integration of renewable energy sources: A survey. IEEE Trans. Ind. Electron., 53: 1002-1016.
CrossRef | Direct Link | Chung, S.K., 2000. A phase tracking system for three phase utility interface inverters. IEEE Trans. Power Electron., 15: 431-438.
CrossRef | Guo, X.Q. and W.Y. Wu, 2013. Simple synchronisation technique for three-phase grid-connected distributed generation systems. IET. Renewable Power Gener., 7: 55-62.
CrossRef | Direct Link | Kanchev, H., D. Lu, F. Colas, V. Lazarov and B. Francois, 2011. Energy management and operational planning of a microgrid with a PV-based active generator for smart grid applications. IEEE. Trans. Ind. Electron., 58: 4583-4592.
CrossRef | Direct Link | Lal, V.N. and S.N. Singh, 2015. Control and performance analysis of a single-stage utility-scale grid-connected PV system. IEEE. Syst. J., 11: 1601-1611.
CrossRef | Direct Link | Magdy, G., G. Shabib, A.A. Elbaset and Y. Mitani, 2019. Renewable power systems dynamic security using a new coordination of frequency control strategy based on virtual synchronous generator and digital frequency protection. Intl. J. Electr. Power Energy Syst., 109: 351-368.
CrossRef | Direct Link | Meneses, D., F. Blaabjerg, O. Garcia and J.A. Cobos, 2012. Review and comparison of step-up transformerless topologies for photovoltaic AC-module application. IEEE. Trans. Power Electron., 28: 2649-2663.
CrossRef | Direct Link | Moukhtar, I., A.A. Elbaset, A.Z. El Dein, Y. Qudaih and Y. Mitani, 2018. Concentrated solar power plants impact on PV penetration level and grid flexibility under Egyptian climate. AIP. Conf. Proc., Vol. 1968, 10.1063/1.5039224
Ozbay, H., S. Oncu and M. Kesler, 2017. SMC-DPC based active and reactive power control of grid-tied three phase inverter for PV systems. Intl. J. Hydrogen Energy, 42: 17713-17722.
Direct Link | Pastor, M. and J. Dudrik, 2013. Predictive current control of grid-tied cascade H-bridge inverter. Automatika, 54: 308-315.
CrossRef | Direct Link | Prodanovic, M. and T.C. Green, 2003. Control and filter design of three-phase inverters for high power quality grid connection. IEEE. Trans. Power Electron., 18: 373-380.
CrossRef | Direct Link | Ramonas, C. and V. Adomavicius, 2013. Research of the converter control possibilities in the grid-tied renewable energy power plant. Elektronika ir Elektrotechnika, 19: 37-40.
CrossRef | Direct Link | Salem, M. and Y. Atia, 2014. Design and implementation of predictive current controller for photovoltaic grid-tie inverter. WSEAS. Trans. Syst. Contr., 9: 597-605.
Direct Link | Sarkar, D.U. and H.S. Dalvi, 2017. Modeling and designing of solar photovoltaic system with 3 phase grid connected inverter. Proceedings of the 2017 2nd International Conference for Convergence in Technology (I2CT’17), April 7-9, 2017, IEEE, Mumbai, India, pp: 1018-1023.
Singh, M., V. Khadkikar and A. Chandra, 2011. Grid synchronisation with harmonics and reactive power compensation capability of a permanent magnet synchronous generator-based variable speed wind energy conversion system. IET. Power Electron., 4: 122-130.
CrossRef | Direct Link | Susheela, N. and P.S. Kumar, 2017. Performance evaluation of carrier based PWM techniques for hybrid multilevel inverters with reduced number of components. Energy Procedia, 117: 635-642.
CrossRef | Direct Link | Suyata, T.I. and S. Po-Ngam, 2014. Simplified active power and reactive power control with MPPT for three-phase grid-connected photovoltaic inverters. Proceedings of the 2014 11th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON’14), May 14-17, 2014, IEEE, Nakhon Ratchasima, Thailand, pp: 1-4.
Suyata, T.I., S. Po-Ngam and C. Tarasantisuk, 2015. The active power and reactive power control for three-phase grid-connected photovoltaic inverters. Proceedings of the 2015 12th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON’15), June 24-27, 2015, IEEE, Hua Hin, Thailand, pp: 1-6.
Yan, L., X. Li, H. Hu and B. Zhang, 2011. Research on SVPWM inverter technology in wind power generation system. Proceedings of the 2011 International Conference on Electrical and Control Engineering, September 16-18, 2011, IEEE, Yichang, China, pp: 1220-1223.
Yao, Z., L. Xiao and J.M. Guerrero, 2015. Improved control strategy for the three-phase grid-connected inverter. IET. Renewable Power Gener., 9: 587-592.
CrossRef | Direct Link |