Abdul W. Kumar, M.D. Mufti, and M.Y. Zargar


  1. [1] G. Chicco and P. Mancarella, Distributed multi-generation: A comprehensive view, Renewable and Sustainable Energy Reviews, 13 (3), 2009, 535–551.
  2. [2] S. D’Arco, J.A. Suul, and O.B. Fosso, A Virtual Synchronous Machine implementation for distributed control of power converters in SmartGrids, Electric Power Systems Research, 122, 2015, 180–97.
  3. [3] H. Bevrani, T. Ise, and Y. Miura, Virtual synchronous generators: A survey and new perspectives, International Journal of Electrical Power and Energy Systems, 54, 2014, 244–254.
  4. [4] S. Barcellona, Y. Huo, R. Niu, L. Piegari, and E. Ragaini, Control strategy of virtual synchronous generator based on virtual impedance and band-pass damping, 2016 Int. Symp. on Power Electronics, Electrical Drives, Automation and Motion, SPEEDAM 2016, Anacapri, Italy, 2016, 1354–1362.
  5. [5] J. Driesen and K. Visscher, Virtual synchronous generators, IEEE Power and Energy Society 2008 General Meeting: Conversion and Delivery of Electrical Energy in the 21st Century, PES, Pittsburgh, PA, USA, 2008, 1–3.
  6. [6] A. Syed and M.D. Mufti, Automatic generation control of a wind embedded two-area power system, interconnected through AC/DC transmission system, International Journal of Industrial Electronics and Drives, 4(4), 2018, 189.
  7. [7] S.J. Iqbal, M.D. Mufti, S.A. Lone, and I. Mushtaq, Intelligently controlled superconducting magnetic energy storage for improved load frequency control, International Journal of Power and Energy Systems, 29(4), 2009, 241–254.
  8. [8] J. Morren, S.W. de Haan, W.L. Kling, and J.A. Ferreira, Wind turbines emulating inertia and supporting primary frequency control, IEEE Transactions on Power Systems, 21(1), 2006, 433–434.
  9. [9] M.Y. Zargar, M.D. Mufti, and S.A. Lone, Adaptive predictive control of a small capacity SMES unit for improved frequency control of a wind-diesel power system, IET Renewable Power Generation, 11(14), 2017, 1832–1840.
  10. [10] M. Alizadeh Bidgoli and S.M.T. Bathaee, Full-state variables control of a grid-connected pumped storage power plant using non-linear controllers, Electric Power Components and Systems, 43(3), 2015, 260–270.
  11. [11] M. Alizadeh Bidgoli, S.M. Bathaee, and A. Shabani, Design a nonlinear auxiliary input for DFIG-based application using Lyapunov theory, PEDSTC 2014—5th Annu. Int. Power Electronics, Drive Systems and Technologies Conf., PEDSTC, Tehran, Iran, 2014, 102–107.
  12. [12] M.R.I. Sheikh and A.B.M. Nasiruzzaman, Transient stability enhancement of wind generator by PWM voltage source converter and chopper controlled SMES unit, Journal of Scientific Research, 1(2), 2009, 226–235.
  13. [13] H. Ahsan and M.D. Mufti, Comprehensive power system stability improvement with ROCOF controlled SMES, Electric Power Components and Systems, 48, 2020, 162–173.
  14. [14] A. Golshani, M. Alizadeh Bidgoli, and S. Bathaee, Design of optimized sliding mode control to improve the dynamic behavior of PMSG wind turbine with NPC back-to-back converter, International Review of Electrical Engineering, 8, 2013, 1170–1180.
  15. [15] T. Kerdphol, M. Watanabe, Y. Mitani, and V. Phunpeng, Applying virtual inertia control topology to SMES system for frequency stability improvement of low-inertia microgrids driven by high renewables, Energies, 12(20), 2019, 3902.
  16. [16] J. Alipoor, Y. Miura, and T. Ise, Power system stabilization using virtual synchronous generator with alternating moment of inertia, IEEE Journal of Emerging and Selected Topics in Power Electronics, 3(2), 2015, 451–458.
  17. [17] D. Li, Q. Zhu, S. Lin, and X.Y. Bian, A self-adaptive inertia and damping combination control of VSG to support frequency stability, IEEE Transactions on Energy Conversion, 32(1), 2017, 397–398.
  18. [18] A. Karimi, Y. Khayat, M. Naderi, et al., Inertia response improvement in AC microgrids: a fuzzy-based virtual synchronous generator control, IEEE Transactions on Power Electronics, 35(4), 2020, 4321–4331.
  19. [19] K. Shi, H. Ye, W. Song, and G. Zhou, Virtual inertia control strategy in microgrid based on virtual synchronous generator technology, IEEE Access, 6, 2018, 27949–27957.
  20. [20] P. Saxena, N. Singh, and A.K. Pandey, Enhancing the dynamic performance of microgrid using derivative controlled solar and energy storage based virtual inertia system, Journal of Energy Storage, 31, 2020, 101613.
  21. [21] N. Sockeel, J. Gafford, B. Papari, and M. Mazzola, Virtual inertia emulator-based model predictive control for grid frequency regulation considering high penetration of inverter-based energy storage system, IEEE Transactions on Sustainable Energy, 2020. DOI: 10.1109/TSTE.2020.2982348.
  22. [22] B. Pal and B. Chaudhuri, Robust control in power systems (Berlin: Springer, 2006).
  23. [23] P.L. Dandeno, R.L. Hauth, and R.P. Schulz, Effects of synchronous machine modeling in large scale system studies, IEEE Transactions on Power Apparatus and Systems, PAS-92(2), 1973, 574–582. 97
  24. [24] K. Padiyar, Power system dynamics: stability and control (New York: Wiley, 1996).
  25. [25] P. Kundur, N.J. Balu, and M.G. Lauby, Power system stability and control (New York: McGraw-Hill, 1994).
  26. [26] V. Akhmatov, Variable-speed wind turbines with doubly-fed induction generators. Part I: modelling in dynamic simulation tools, Wind Engineering, 26(2), 2002, 85–108.
  27. [27] F. Milano and ´A. Ortega, Frequency divider, IEEE Transactions on Power Systems, 32(2), 2017, 1493–1501.
  28. [28] A. Mitra and D. Chatterjee, Stability enhancement of wind farm connected power system using superconducting magnetic energy storage unit, Eighteenth National Power System Conf, NPSC, Guwahati, India, 2014.

Important Links:

Go Back