Virtual Inertia Control Application to Enhance Frequency Stability of Interconnected Power Systems with High Renewable Energy Penetration
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Yasunori Mitani | Thongchart Kerdphol | Fathin Saifur Rahman | F. S. Rahman | Y. Mitani | T. Kerdphol
[1] Ali Feliachi,et al. Robust load frequency control using genetic algorithms and linear matrix inequalities , 2003 .
[2] Yasunori Mitani,et al. Robust decentralized AGC in a restructured power system , 2004 .
[3] S. Tsuji-Iio,et al. Flexible Power Interconnection With SMES , 2006, IEEE Transactions on Applied Superconductivity.
[4] S. Dechanupaprittha,et al. Stabilization of Tie-Line Power Flow by Robust SMES Controller for Interconnected Power System With Wind Farms , 2007, IEEE Transactions on Applied Superconductivity.
[5] Li Wang,et al. Small-Signal Stability Analysis of an Autonomous Hybrid Renewable Energy Power Generation/Energy Storage System Part I: Time-Domain Simulations , 2008, IEEE Transactions on Energy Conversion.
[6] Issarachai Ngamroo. Robust SMES controller design based on inverse additive perturbation for stabilization of interconnected power systems with wind farms , 2010 .
[7] S Islam,et al. Application of SMES Unit in Improving the Performance of an AC/DC Power System , 2011, IEEE Transactions on Sustainable Energy.
[8] Tarek Hassan Mohamed,et al. Decentralized model predictive based load frequency control in an interconnected power system , 2011 .
[9] Yasunori Mitani,et al. Intelligent Frequency Control in an AC Microgrid: Online PSO-Based Fuzzy Tuning Approach , 2012, IEEE Transactions on Smart Grid.
[10] T. Senjyu,et al. Frequency control improvement in a PV-diesel hybrid power system with a virtual inertia controller , 2012, 2012 7th IEEE Conference on Industrial Electronics and Applications (ICIEA).
[11] Luiz A. C. Lopes,et al. Self-Tuning Virtual Synchronous Machine: A Control Strategy for Energy Storage Systems to Support Dynamic Frequency Control , 2014, IEEE Transactions on Energy Conversion.
[12] Jon Are Suul,et al. Small-signal modeling and parametric sensitivity of a virtual synchronous machine in islanded operation , 2015 .
[13] Clemens Jauch,et al. Design of a System Substituting Today’s Inherent Inertia in the European Continental Synchronous Area , 2016 .
[14] Sinan Kufeoglu,et al. Macroeconomic assessment of voltage sags , 2016 .
[15] Jia Liu,et al. Comparison of Dynamic Characteristics Between Virtual Synchronous Generator and Droop Control in Inverter-Based Distributed Generators , 2016, IEEE Transactions on Power Electronics.
[16] Lieven Vandevelde,et al. Droop Control as an Alternative Inertial Response Strategy for the Synthetic Inertia on Wind Turbines , 2016, IEEE Transactions on Power Systems.
[17] Fangxing Li,et al. Coordinated Microgrid Frequency Regulation Based on DFIG Variable Coefficient Using Virtual Inertia and Primary Frequency Control , 2016, IEEE Transactions on Energy Conversion.
[18] Dong Chen,et al. Integration of DC Microgrids as Virtual Synchronous Machines Into the AC Grid , 2017, IEEE Transactions on Industrial Electronics.
[19] Yasunori Mitani,et al. Virtual Inertia Control-Based Model Predictive Control for Microgrid Frequency Stabilization Considering High Renewable Energy Integration , 2017 .
[20] Timothy M. Hansen,et al. Virtual Inertia: Current Trends and Future Directions , 2017 .
[21] Haile-Selassie Rajamani,et al. A novel approach to frequency support in a wind integrated power system , 2017 .
[22] Hossam A. Gabbar,et al. Control and EMS of a Grid-Connected Microgrid with Economical Analysis , 2018 .
[23] Yasunori Mitani,et al. Robust Virtual Inertia Control of an Islanded Microgrid Considering High Penetration of Renewable Energy , 2018, IEEE Access.