Zaheer Farooq and Nasim Ullah


  1. [1] L.H. Hansen, L. Helle, F. Blaabjerg, E. Ritchie, S. Munk-Nielsen, H. Bindner, P. Sørensen, and B. Bak-Jenseen, Conceptual survey of generators and power electronics for wind turbines, Risø Nat. Lab., Roskilde, Denmark, Tech, 2001, Rep. Risø-R-1205(EN), ISBN 87-550-2743-8.
  2. [2] R.W. de Doncker, D.M. Divan, and M.H. Kheraluwalal, A three phase soft-switched high-power density DC/DC converter for high power applications, Proc. IEEE Industrial Applications Society Annual Meeting, Pittsburg, PA, USA 1, 1998, 796–805. 154
  3. [3] B. Gu, J.-S. Lai, N. Kees, and C. Zheng, Hybrid-switching full-bridge dc–dc converter with minimal voltage stress of bridge rectifier, reduced circulating losses, and filter requirement for electric vehicle battery chargers, IEEE Transactions on Power Electronics, 28(3), 2013, 1132–1144.
  4. [4] Y. Shi, R. Li, Y. Xue, and H. Li, Optimized operation of current-fed dual active bridge DC–DC converter for PV applications, IEEE Transactions on Industrial Electronics, 62(11), 2015, 6986–6995.
  5. [5] H. Tao, A. Kotsopoulos, J.L. Duarte, and M.A.M. Hendrix, Multi-input bidirectional dc–dc converter combining dc-link and magnetic-coupling for fuel cell systems, Proc. 40th IEEE IAS Annual Meeting, 3, 2005, 2021–2028.
  6. [6] C.-C. Hua, C.-W. Chuang, C.-W. Wu, and D.-J. Chuang, Design and implementation of a digital high-performance photovoltaic lighting system, Proc. ICIEA, 2007, 2583–2588.
  7. [7] N. Kasa, Y. Harada, T. Ida, and A.K.S. Bhat, Zero-current transitions converters for independent small-scale power network system using lower power wind turbines, Proc. IEEE International Symposium on Power Electronics, Electrical Drives, Automation and Motion, 2006, 1206–1210.
  8. [8] R.T. Naayagi, and N.E. Mastorakis, Performance verification of dual active bridge DC–DC converter, Recent Researches in Applications of Electrical and Computer Engineering, Bulgaria.
  9. [9] H. Bai, and C. Mi, Eliminate reactive power and increase system efficiency of isolated bidirectional dual-active-bridge dc–dc converters using novel dual-phase-shift control, IEEE Transactions on Power Electronics, 23(6), 2008, 2905–2914.
  10. [10] Z. Biao, Y. Qingguang, and S. Weixin, Bi-directional full bridge DC–DC converters with dual-phase-shifting control and its backflow power characteristic analysis, Proceedings of the CSEE, 32, 2012, 43–50.
  11. [11] Y.A. Harrye, K.H. Ahmed, G.P. Adam, and A.A. Aboushady, Comprehensive steady state analysis of bidirectional dual active bridge DC/DC converter using triple phase shift control, IEEE 23rd International Symposium on Industrial Electronics (ISIE), Istanbul, Turkey, 2014, 437–442.
  12. [12] D. Segaran, B.P. McGrath, and D.G. Holmes, Adaptive dynamic control of a bi-directional DC–DC converter, Proc. IEEE Energy Conversion Congress and Exposition, Atlanta, GA, USA, 2010, 1442–1449.
  13. [13] H. Akagi, and R. Kitada, Control and design of a modular multilevel cascade system using bidirectional isolated dc–dc converters, IEEE Transactions on Power Electronics, 26(9), 2011, 2457–2464.
  14. [14] Y. Xie, J. Sun, and J.S. Freudenberg, Power flow characterization of a bidirectional galvanically isolated high-power dc/dc converter over a wide operating range, IEEE Transactions on Power Electronics, 25(1), 2010, 54–66.
  15. [15] L. Xue, Z. Shen, D. Boroyevich, P. Mattavelli, and D. Diaz, Dual active bridge-based battery charger for plug-in hybrid electric vehicle with charging current containing low frequency ripple, IEEE Transactions on Power Electronics, 30(12), 2015, 7299–7307.
  16. [16] P. Gawthrop, Self-tuning PID controllers: Algorithms and implementation, IEEE Transactions on Automatic Control, 31(3), 1986, 201–209.
  17. [17] K.J. Astrom, and T.H. Agglund, PID controllers: theory, design, and tuning, Research Triangle Park, NC: Instrument Society of America, 1995.
  18. [18] J.-B. He, Q.-G. Wang, and T.-H. Lee, PI/PID controller tuning via LQR approach, Chemical Engineering Science, 55(13), 2000, 2429–2439.
  19. [19] S. Sumathi and Bansilal, Artificial neural network application for voltage control and power flow control in power systems with UPFC, Proc. IEEE International Conference on Emerging Research in Electronics, Computer Science and Technology, USA, 2015.
  20. [20] R. Shaffer. Fundamentals of power electronics with MATLAB, Career and Professional Group, a division of Thomson Learning. Inc., Boston, MA, 2007.
  21. [21] N. Ullah, M. Asghar Ali, A. Ibeas, and J. Herrera, Adaptive fractional order terminal sliding mode control of a doubly fed induction generator-based wind energy system, IEEE Access, 5, 2015, 21368–21381. doi:10.1109/ACCESS.2017.2759579.
  22. [22] N. Ullah, M.A. Ali, R. Ahmad, and A. Khattak, Fractional order control of static series synchronous compensator with parametric uncertainty, IET Generation, Transmission, & Distribution, 11(1), 2017, 289–302.
  23. [23] N. Ullah, M.I. Khattak, and W. Khan, Fractional order fuzzy terminal sliding mode control of aerodynamics load simulator. Proc. Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 229(14), 2015, 2608–2619.
  24. [24] N. Ullah, S.P. Wang, M.I. Khattak, and M. Shafi, Fractional order adaptive fuzzy sliding mode controller for a position servo system subjected to aerodynamic loading and nonlinearities, Aerospace Science and Technology, 43, 2015, 381–387.
  25. [25] J. M. Zurada, A. Malinowski, and P. Przestrzelski, Modified Hebbian learning rule for single layer learning, IEEE International Symposium on Circuits and Systems, Chicago, IL, 1993, Vol. 4, 2407–2410.
  26. [26] A.L.L.F. Murari, J.A.T. Altuna, R.V. Jacomini, C.M.R. Osorio, J.S.S. Chaves, and A.J.S. Filho, A proposal of project of PI controller gains used on the control of doubly-fed induction generators, IEEE Latin America Transactions, 15(2), 2017, 173–180, doi: 10.1109/TLA.2017.7854609.
  27. [27] C.M. Rocha-Osorio, J.S. Solıs-Chaves, I.R.S. Casella, C.E. Capovilla, J.L. Azcue Puma, A.J. Sguarezi Filho, GPRS/EGPRS standards applied to DTC of a DFIG using fuzzy – PI controllers, International Journal of Electrical Power & Energy Systems, 93, 2017, 365–373.

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