PREDICTION-BASED ADAPTIVE CONTROL OF SMES FOR MULTI-AREA POWER SYSTEMS

Asima Syed and Mairaj ud din Mufti

References

  1. [1] P. Kundur, N.J. Balu, and M.G. Lauby, Power system stability and control, vol. 7 (New York: McGraw-Hill, 1994).
  2. [2] G. Sharma, K.R. Niazi, R.C. Bansal, et al., Adaptive fuzzy critic based control design for AGC of power system connected via AC/DC tie-lines, IET Generation, Transmission & Distribution, 11(2), 2017, 560–569.
  3. [3] M.D. Mufti, S.J. Iqbal, S.A. Lone, and Q. Ain, Supervisory adaptive predictive control scheme for supercapacitor energy storage system, IEEE Systems Journal, 9(3), 2015, 1020–1030.
  4. [4] T.-S. Tsay, Load-frequency control of interconnected power system with governor backlash nonlinearities, International Journal of Electrical Power and Energy Systems, 33(9), 2011, 1542–1549 [online], http://www.sciencedirect.com/science/article/pii/S0142061511001141.
  5. [5] M.H. Ali, B. Wu, and R.A. Dougal, An overview of smes applications in power and energy systems, IEEE transactions on sustainable energy, 1(1), 2010, 38–47.
  6. [6] H. Ahsan and M.D. Mufti, Sweeping power system stabilisation with a parametric fuzzy predictive control of a generalised energy storage device, IET Generation, Transmission & Distribution, December 2020, [online], https://digitallibrary.theiet.org/content/journals/10.1049/iet-gtd.2020.0940
  7. [7] H. Jiang and C. Zhang, A method of boosting transient stability of wind farm connected power system using superconducting magnetic energy storage unit, IEEE Transactions on Applied Superconductivity, 29(2), 2019, 1–5.
  8. [8] G. Magdy, G. Shabib, A.A. Elbaset, and Y. Mitani, Optimized coordinated control of LFC and smes to enhance frequency stability of a real multi-source power system considering high renewable energy penetration, Protection and Control of Modern Power Systems, 3, 2018, 12.
  9. [9] H. Ahsan and M.D. Mufti, Comprehensive power system stability improvement with ROCOF controlled SMES, Electric Power Components and Systems, 48(1–2), 2020, 162–173 [online], https://doi.org/10.1080/15325008.2020.1731878.
  10. [10] S. Padhan, R.K. Sahu, and S. Panda, Automatic generation control with thyristor controlled series compensator including superconducting magnetic energy storage units, Ain Shams Engineering Journal, 5(3), 2014, 759–774 [online], http://www.sciencedirect.com/science/article/pii/S2090447914000409.
  11. [11] S. Iqbal, M. Mufti, S. Lone, and I. Mushtaq, Intelligently controlled superconducting magnetic energy storage for improved load frequency control, International Journal of Power & Energy Systems, 29(4), 2009, 241.
  12. [12] H. Ahsan and M.-U.D. Mufti, Distributed storage approach versus singular storage approach: A dynamic stability evaluation, International Journal of Power and Energy Systems, 39(1), 2019
  13. [13] M.Y. Zargar, M.U.-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.
  14. [14] M.-U.D. Mufti and S. Un Nisa (in press), Constrained discrete mode control of supercapacitor energy storage system for improved AGC of a multi-area power system with effects of wind power, International Journal of Power Electronics, 2019.
  15. [15] S. Tripathy and K. Juengst, Sampled data automatic generation control with superconducting magnetic energy storage in power systems, IEEE Transactions on Energy Conversion, 12(2), 1997, 187–192.
  16. [16] H. Bevrani, Robust power system frequency control (Berlin: Springer, 2009), 85.
  17. [17] H. Ahsan and M.-u.D. Mufti, Systematic development and application of a fuzzy logic equipped generic energy storage system for dynamic stability reinforcement, International Journal of Energy Research, 44(11), 2020, 8974–8987.
  18. [18] A. Waheed, M.-U.D. Mufti, and M. Zargar, (in press) Dynamic performance enhancement of wind penetrated power system using smes as virtual synchronous generator, International Journal of Power and Energy Systems, vol. 41, 2021.
  19. [19] J.R. Noriega and H. Wang, A direct adaptive neural-network control for unknown nonlinear systems and its application, IEEE Transactions on Neural Networks, 9(1), 1998, 27–34.
  20. [20] S.H. Zak, Systems and control, vol. 198 (New York: Oxford University Press, 2003).
  21. [21] B. Widrow and M.A. Lehr, 30 years of adaptive neural networks: Perceptron, madaline, and backpropagation, Proceedings of the IEEE, 78(9), 1990, 1415–1442.
  22. [22] S. Dechanupaprittha, N. Sakamoto, K. Hongesombut, M. Watanabe, Y. Mitani, and I. Ngamroo, Design and analysis of robust SMES controller for stability enhancement of interconnected power system taking coil size into consideration, IEEE Transactions on Applied Superconductivity, 19(3), 2009,2019–2022.
  23. [23] M. Gopal, Digital Cont & State Var Met. (New York: McGraw-Hill, 2012) [online], https://books.google.co.in/books?id=4VvT5RtneggC
  24. [24] P.S.C. Nair, S.C. Tripathy, and R. Balasubramanian, Capacitive energy storage: An aid for damping frequency and tie-line power oscillations, TENCON’91—Region 10 International Conf. on EC3-Energy, Computer, Communication and Control Systems, New Delhi, India, vol. 1, 1991, 377–381.

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