Zhixin Miao, Alexander Domijan, and Lingling Fan


  1. [1] Z. Miao, Modeling and dynamic stability of distributed gener-ations, Ph.D. Thesis, West Virginia University, Morgantown,WV, 2002.
  2. [2] Z. Miao, A. Domijan, and L. Fan, Investigation of micro-grids with both inverter interfaced and direct ac connecteddistributed energy resources, IEEE Transactions on PowerDelivery, 26(3), 2011, 1634–1642.
  3. [3] Z. Miao, A. Domijan, and L. Fan, Analysis of negative sequencecompensation based unbalance control in distributed energyresources interfacing inverters, International Journal of Powerand Energy Systems, 32(3), 2012, 1–13.
  4. [4] Z. Miao and L. Fan, Modeling and small signal analysis of apmsg-based wind generator with sensorless maximum powerextraction, in IEEE PES General Meeting, San Diego, CA,2012.
  5. [5] Z. Miao, M. Choudhry, R.L. Klein, and L. Fan, Study of a fuelcell power plant in power distribution system. Part I. Dynamicmodel, IEEE Power Engineering Society General Meeting,Denver, CO, 2004, 2220–2225.
  6. [6] Z. Miao, M. Choudhry, R.L. Klein, and L. Fan, Study of afuel cell power plant in power distribution system. Part II.Stability control, IEEE Power Engineering Society GeneralMeeting, Denver, CO, 2004, 2226–2231.
  7. [7] E. Barklund, N. Pogaku, M. Prodanovic, C. Hernandez-Aramburo, and T. Green, Energy management in autonomousmicrogrid using stability-constrained droop control of invert-ers, IEEE Transactions on Power Electronics, 23(5), 2008,2346–2352.
  8. [8] Y. Mohamed and E. El-Saadany, Adaptive decentralized droopcontroller to preserve power sharing stability of paralleled in-verters in distributed generation microgrids, IEEE Transac-tions on Power Electronics, 23(6), 2008, 2806–2816.
  9. [9] F. Peng, Y. Li, and L.M. Tolbert, Control and protection ofpower electronics interfaced distributed generation systems ina customer-driven microgrid, Proceedings of IEEE Power &Energy Society General Meeting, Calgary, Canada, 2009.
  10. [10] H.L. Willis and W.G. Scott, Distributed power generation:Planning and evaluation (New York, Basel: Marcel Dekker,Inc., 2000).
  11. [11] S. Krishnamurthy, T. Jahns, and R. Lasseter, The operationof diesel gensets in a CERTS microgrid, Proceedings of IEEEPower & Energy Society General Meeting, Pittsburgh, PA,2008.
  12. [12] S.V. Iyer, M.N. Belur, and M.C. Chandorkar, A generalizedcomputational method to determine stability of a multi invertermicrogrid, to appear, IEEE Transactions on Power Electronics,25(9), 2010, 2420–2432.
  13. [13] C. Hochgraf and R. Lasseter, STATCOM controls for opera-tion with unbalanced voltages, IEEE Transactions on PowerDelivery, 13(2), 1998, 538–544.
  14. [14] B. Blazic and I. Papic, Improved D-Statcom control for opera-tion with unbalanced currents and voltages, IEEE Transactionson Power Delivery, 21(1), 2006, 225–231.
  15. [15] K. Li, J. Liu, Z. Wang, and B. Wei, Strategies and oper-ating point optimization of STATCOM control for voltageunbalance mitigation in three-phase three-wire systems, IEEETransactions on Power Delivery, 22(1), 2007, 413–422.
  16. [16] Q. Song and W. Liu, Control of a cascade STATCOM with starconfiguration under unbalanced conditions, IEEE Transactionson Power Electronics, 24(1), 2009, 45–48.
  17. [17] G. Escobar, A. Stankovic, and P. Mattavelli, An adaptive con-troller in stationary reference frame for D-STATCOM in unbal-anced operation, IEEE Transactions on Industrial Electronics,51(2), 2004, 401–409.
  18. [18] A. Leon, J. Mauricio, J. Solsona, and A. Gomez-Exposito,Software sensor-based STATCOM control under unbalancedconditions, IEEE Transactions on Power Delivery, 24(3), 2009,1623–1632.
  19. [19] M. Hojo, Y. Iwase, T. Funabashi, and Y. Ueda, A methodof three-phase balancing in microgrid by photovoltaic gener-ation systems, 13th Power Electronics and Motion ControlConference (EPE-PEMC), Poznan, Poland, 2008.
  20. [20] C. Sao and P. Lehn, Voltage balancing of converter fed micro-grids with single phase loads, Proc. IEEE Power and EnergySociety General Meeting, Pittsburgh, PA, 2008.
  21. [21] W. Qiao, W. Zhou, J.M. Aller, and R.G. Harley, Wind speedestimation based sensorless output maximization control for awind turbine driving a DFIG, IEEE Transactions on PowerElectronics, 23(3), 2008, 1156–1169.
  22. [22] H. Li, K.L. Shi, and P. McLaren, Neural-network-based sensor-less maximum wind energy capture with compensated powercoefficient, IEEE Transactions on Industry Applications, 41(6),2005, 1548–1556.
  23. [23] Y. Lei, A. Mullane, G. Lightbody, and R. Yacamini, Modelingof the wind turbine with a doubly fed induction generatorfor grid integration studies, IEEE Transactions on EnergyConversion, 21, 2006, 257–264.
  24. [24] L. Fan, Z. Miao, and X. Wang, Sensorless maximum powerpoint tracking in multi-type wind energy conversion systems,Proceedings of the 48th IEEE conference on Decision andControl, Shanghai, China, 2009, 6823–6828.
  25. [25] F. Katiraei, M. Iravani, and P. Lehn, Micro-grid autonomousoperation during and subsequent to islanding process, IEEETransactions on Power Delivery, 20(1), 2005, 248–257.
  26. [26] IEEE recommended practice for industrial and commercialpower system analysis, Technical Report, IEEE Standard 399-1990, 1990. doi: 10.1109/IEEESTD.1990.115569
  27. [27] K. Yeager and J. Willis, Modeling of emergency diesel genera-tors in an 800 megawatt nuclear power plant, IEEE Transac-tions on Power Systems, 8(3), 2003, 433–441.
  28. [28] M. Rahman, A. Osheiba, T. Radwan, and E. Abdin, Modelingand controller design of an isolated diesel engine permanentmagnet synchronous generator, IEEE Transactions on EnergyConversion, 11(2), 1996, 324–330.
  29. [29] M. Klein, G. Rogers, and P. Kundur, A fundamental studyof inter-area oscillations in power systems, IEEE Transactionson Power Systems, 6, 1991, 914–921.
  30. [30] Z. Jiang and X. Yu, Active power – voltage control scheme forislanding operation of inverter-interfaced microgrids, Proc. ofIEEE Power Engineering Society General Meeting, Calgary,Alberta, Canada, 2009.
  31. [31] V. Akhmatov, A.H. Nielsen, J.K. Pedersen, and O. Nymann,Variable-speed wind turbines with multi-pole synchronous per-manent magnet generator. Part I. Modeling in dynamic simu-lation tools, Wind Engineering, 27, 2003, 531–548.
  32. [32] A.D. Hansen and G. Michalke, Multi-pole permanent magnetsynchronous generator wind turbines grid support capabilityin uninterrupted operation during grid faults, IET RenewablePower Generation, 3, 2009, 333–348.
  33. [33] K. Tan and S. Islam, Optimum control strategies in energyconversion of PMSG wind turbine system without mechanicalsensors, IEEE Transactions on Energy Conversion, 19(2),2004, 392–399.
  34. [34] F. Wu, X.P. Zhang, and P. Ju, Small signal stability analysisand control of the wind turbine with the direct-drive perma-nent magnet generator integrated to the grid, Electric PowerSystems Research, 79(12), 2009, 1661–1667.
  35. [35] J.B. Ekanayake, L. Holdsworth, X. Wu, and N. Jenkins,Dynamic modeling of doubly fed induction generator windturbines, IEEE Transactions on Power Systems, 18, 2003,803–809.158

Important Links:

Go Back