[1] Nguy n Hoàng H i (2009), Nghiên c u đ c tính ph ng c a máy phát không đ ng
b ngu n kép (rotor dây qu n) và đ xu t c u trúc đi u khi n trên c s nguyên lý h ph ng. án t t nghi p K49, i h c bách khoa Hà N i.
[2] ng Danh Ho ng (2008), Nghiên c u c i thi n ch t l ng h th ng đi u khi n
máy phát đi n không đ ng b ngu n kép b ng ph ng pháp đi u khi n phi tuy n,
Báo cáo t ng k t đ tài nghiên c u khoa h c c p B , Trung tâm h c li u - i h c
Thái Nguyên, Mã s B2008 TN02_06.
[3] Nguy n Phùng Quang (1996), i u khi n t đ ng truy n đ ng đi n xoay chi u 3
pha, Nxb Khoa h c k thu t Hà N i.
[4] Nguy n Phùng Quang, Dittrich A. (2002), Truy n đ ng đi n thông minh, Nxb
Khoa h c k thu t Hà N i.
[5] Cao Xuân Tuy n (2008), T ng h p các thu t toán phi tuy n trên c s ph ng pháp
backstepping đ đi u khi n máy đi n d b ngu n kép trong h th ng máy phát đi n s c gió, Lu n án ti n s k thu t, i h c bách khoa Hà N i.
Ti ng Anh:
[6] Abad G., Bobrowska-Rafal M., Rafal K., and Jasinski M. (2009), “Control of
PWM rectifier under grid voltage dips”, Bulletin of the Polish Academy of Science, 57(4).
[7] Abellan A., Benavent J. M., Garcera G., and Cerver D. (2002), “Fixed frequency
current controller applied to shunt active filters with upf control in four-wire power
systems”, IEEE 2002 28th Annual Conference of the Industrial Electronics Society,
1, pp. 780– 785.
[8] Akagi H., Watanabe E. H., and Aredes M. (2007), Instantaneous Power Theory and
Applications to Power Conditioning, Wiley-IEEE Press.
[9] Alepuz S., Busquets S., Bordonau J., Pontt J., Silva C., and Rodriguez J. (2007), “Fast on-line symmetrical components separation method for synchronization and
control purposes in three phase distributed power generation systems”, European
Conference on Power Electronics and Applications.
[10] Alepuz S., Busquets S., Bordonau J., Pontt J., Silva C., and Rodriguez J. (2007), “Balanced grid currents in three-level voltage-source inverters connected to the utility under distorted condition using symmetrical components and linear
quadratic regulator”, European Conference on Power Electronics and
Applications..
[11] Alepuz S., Busquets-Monge S., Bordonau J., Martinez-Velasco J. A., Silva C. A., Pontt J., and Rodriguez J. (2009), “Control strategies based on symmetrical
components for grid-connected converters under voltage dips”, IEEE Transactions
on Industrial Electronics, 56(6),pp. 2162 – 2173.
[12] American Wind Energy Association (2008), AWEA Rankings ReportYear Ending (adsbygoogle = window.adsbygoogle || []).push({});
2007, Washington DC.
[13] Andreas Petersson (2005), Analysis, Modeling and Control of Doubly-Fed
Induction Generators for Wind Turbines, PhD thesis, Chalmers University of Technology.
[14] Application Report (1997), Clarke and Park Transforms on the TMS320C2xx, Texas Instruments.
[15] Arbi J., Belkhodja I. S., and Gomez S. A. (2007), “Control of a dfig-based wind system in presence of large grid faults analysis of voltage ride through capability”,
9th International Conference on Electrical Power Quality and Utilisation.
[16] Balas L. Y., Fingersh M. J., Johnson L.J ., Pao K. E. (2006), “Control of variable-speed wind turbines standard and adaptive techniques for maximizing
energy capture”, IEEE Control Systems Magazine, 26, pp. 70 - 81.
[17] Barbara H. Kenny, and Robert D. Lorenz (2002), “Stator- and rotor-flux-based
dead-beat direct torque control of induction machines”, IEEE Transactions on
Industry Applications, 39, pp. 1093 - 1101.
[18] Batlle C., Cerezo A. D., and Ortega R. (2007), “A stator voltage oriented pi
controller for the doubly-fed induction machine”, American Control Conference,
pp. 5438 - 5443.
[19] Bianchi F.F., De Battista H., and Mantz R.J. (2006), Wind Turbine Control
Systems Principles, Modelling and Gain Scheduling Design. Springer.
[20] Blaabjerg F., and Chen Z. (2006), “Power Electronics for Modern Wind “
Turbines, Morgan & Claypool Publishers.
[21] Bongiorno M., Svensson J., and Sannino A. (2004), “Dynamic performance of current controllers for grid-connected voltage source converters under unbalanced
[22] Bongiorno M. (2007), On Control of Grid-connected Voltage Source Converters - Mitigation of Voltage Dips and Subsynchronous Resonances, PhD thesis, Chalmers University of Technology.
[23] Boukhezzar B., Siguerdidjane H. (2009), “Nonlinear control with wind estimation
of a dfig variable speed wind turbine for power capture optimization”, Energy
Conversion and Management, 50, pp. 885 - 892.
[24] Buja G., andela M. C., and Menis R. (1999), “A novel direct control scheme for
svm inverter-fed induction motor drives”, Proceedings of the IEEE International
Symposium on Industrial Electronics, 3, pp. 1267–1272.
[25] Cadirci I., and Ermis M. (1992), “Double-output induction generator operating at subsynchronous and supersynchronous speeds steady-state performance
optimisation and wind-energy recovery”, IEE Proceedings-B, 139, pp. 429 –
442.
[26] Capehart B. L. (2007), Encyclopedia of Energy Engineering and Technology. (adsbygoogle = window.adsbygoogle || []).push({});
CRC.
[27] Casadei D., Serra G., and Tani A. (1997), “Analytical investigation of torque and
flux ripple in dtc schemesfor induction motors”, International Conference on
Industrial Electronics, 2, pp. 552 - 556.
[28] Datta R., and Ranganathan V. T. (2002), “Variable-speed wind power generation using doubly fed wound rotor induction machine-a comparison with alternative
[29] Datta R., and Ranganathan V. T. (2003), “A method of tracking the peak power
points for a variable speed wind energy conversion system”, IEEE Transactions
on nergy Conversion, 18, pp. 163 - 168.
[30] De La Rosa F.C. (2006), Harmonics and Power Systems, CRC.
[31] Ekanayake J. B., Holdsworth L., Wu X. G., and Jenkins N. (2003), “Dynamic
modeling of doubly fed induction generator wind turbines”, IEEE Transactions on
Power Systems, 18, pp. 803– 809.
[32] Ekanayake J., and Jenkins N. (2004), “Comparison of the response of doubly fed and fixed-speed induction generator wind turbines to changes in network
frequency”, IEEE Transactions on Energy Conversion, 19, pp. 800 - 802.
[33] Emami-Naeini A., and Franklin G. (1982), “Deadbeat control and tracking of
discretetime systems”, IEEE Transactions on Automatic Control, 27, pp. 176–
181.
[34] Erlich I., Wrede H., and Feltes C. (2007), “Dynamic behavior of dfig-based wind
turbines during grid faults”, Power Conversion Conference (PCC)Nagoya Japan,
pp. 1195–1200.
[35] European Wind Energy Association (2008), EWEA 2007 annual report, Belgium.
[36] Fahmy M. M., and O’Reilly J. (1983), “Dead-beat control of linear discrete-time systems”, International Journal of Control, 37, pp. 685 - 705.
[37] Fei Wang, Benhabib M. C., Duarte J. L., and Hendrix M. (2009), “Sequence-decoupled resonant controller for three-phase grid-connected
inverters”, Applied Power Electronics Conference and Exposition, pp.121 - 127.
[38] Fei Wang, Duarte J. L., and Hendrix M. (2008), “Control of grid-interfacing
inverters with integrated voltage unbalance correction”, IEEE Power Electronics
Specialists Conference, pp. 310 – 316.
[39] Global Wind Energy Council (2008), Global wind 2007 report, Belgium.
[40] Habetler T. G., Profumo F., Pastorelli M., and Tolbert L. M. (1992), “Direct
torque control of induction machines using space vector modulation”, IEEE (adsbygoogle = window.adsbygoogle || []).push({});
Transactions on Industry Applications, 28, pp. 1045 – 1053.
[41] Heier S. (1998), “Grid integration of wind energy conversion systems”, John
Wiley and Sons, Ltd.
[42] Helle L., and Nielsen S. M. (2001), “Comparison of converter efficiency in large
variable speed wind turbines”, Sixteenth Annual IEEE Applied Power Electronics
Conference and Exposition, 1, pp. 628 - 634.
[43] Hofmann W., and Thieme A. (1998), “Control of a double-fed induction generator
for wind-power plants”, Power Quality Proceedings PCIM’98, Nurnberg, pp.
275 - 282.
[44] Hopfensperger B., Atkinson D. J., and Lakin R. A. (2000), “Stator flux oriented
control of a double-fed induction machine with and without position encoder”, IEE
[45] Nguyen Tien Hung, Scherer C. W., and Scherpen J. M. A. (2007), “Robust performance of self-scheduled LPV control of doubly-fed induction generator in
wind enegy conversion systems”, 12th European Conference on Power
Electronics and Applications, Denmark, CDROM.
[46] Iov F., Blaabjerg F., and Hansen A. D. (2003), “Analysis of a variable-speed wind
energy conversion scheme with doubly-fed induction generator”, International
Journal of Electronics, 90, pp. 779 - 794.
[47] Khan S., and Ahmed G. (2007), Industrial Power Systems. CRC.
[48] Koutroulis E., and Kalaitzakis K. (2006), “Design of a maximum power tracking
system for wind-energy-conversion applications”, IEEE Transactions on
Industrial Electronics, 53, pp. 486 - 494.
[49] Phung Ngoc Lan (2006), Linear and nonlinear control approach to doubly-fed
induction generators in wind power generation, PhD thesis, TU Dresden.
[50] Lehn P.W. (2003), “Direct harmonic analysis of the voltage source converter”,
IEEE Transactions on Power Delivery, 18, pp. 1034 - 1042.
[51] Liao Y., Ran L., Putrus G. A., and Smith K. S. (2003), “Evaluation of the effects of rotor harmonics in a doubly-fed induction generator with harmonic induced speed ripple”, IEEE Transaction on Energy Conversion, 18, pp. 508 - 515.
[52] Lindholm M., and Rasmussen T. W. (2003), “Harmonic analysis of doubly fed
induction generators”. The Fifth International Conference on Power Electronics
[53] Lopez J., Sanchis P., Roboam X., and Marroyo L. (2007), “Dynamic behavior of
the doubly fed induction generator during three-phase voltage dips”, IEEE (adsbygoogle = window.adsbygoogle || []).push({});
Transactions on Energy Conversion, 22, pp. 709 - 717.
[54] Lund T. , Sorensen P. , and Eek J. ( 2007), “Reactive power capability of a wind turbine with doubly fed induction generator”, John Wiley and Sons, Ltd.
[55] Maes J., and Melkebeek J. (1998), “Discrete time direct torque control of induction
motors using back-emf measurement”, The IEEE Industry Applications
Conference, 1, pp. 407 - 414.
[56] Magueed F. A., and Svensson J. (2005), “Control of vsc connected to the grid through lcl-filter to achieve balanced currents”, IndustryApplications Conference, 1(0), pp. 572 - 578.
[57] Mauricio J. M., Leon A.E., Exposito A. G., and Solsona J.A. (2008), “An
adaptive nonlinear controller for dfim-based wind energy conversion systems”,
IEEE transactions on Energy conversion, 23, pp. 1025 - 1035.
[58] Michalke G., and Daniela H. A. (2007), “Voltage grid support of dfig wind
turbines during grid faults”, European Wind Energy Conference and Exhibition,
EWEC 2007.
[59] Molenaar D. P. (2003), Cost-effective Design and Operation of Variable Speed
Wind Turbines, PhD thesis, Delft University Press.
[60] Montenegro Leon A. (2005), Advanced power electronic for wind-power
[61] Morren J., and de Haan S. W. H. (2005), “Ridethrough of wind turbines with
doublyfed induction generator during a voltage dip”, IEEE Transactions on
energy conversion, 20, pp. 435 - 441.
[62] Muljadi C. P., Butterfield E. (2001), “Pitch-controlled variable-speed wind turbine generation”, IEEE Transactions on Industry Applications, 37, pp. 240 - 246.
[63] Novotny D. W., and Lipo T. A. (1996), Vector Control and Dynamics of AC
Drives, Oxford University Press, USA.
[64] Ng. C.H., Ran L., and Bumby J. (2008), “Unbalanced-grid-fault ride-through
control for a wind turbine inverter”, IEEE Transactions on Industry Applications,
44(3), p. 845 - 856.
[65] Ostolaza J. X., Tapia A., Tapia G., and Saenz J. R. (2003), “Modeling and control
of a wind turbine driven doubly fed induction generator”. IEEE Transactions on
Energy Conversion, 18, pp. 194 - 204.
[66] Patel M. R. (1999), Wind and Solar Power Systems. CRC Pess.
[67] Pena R., Clare J. C., and Asher G. M. (1996), “Doubly fed induction generator using back-to-back pwm converters and its application to variable speed
windenergy generation”, IEE Proceedings on Electric Power Applications, 143, (adsbygoogle = window.adsbygoogle || []).push({});
pp. 231 - 241.
[68] Peng Z. and Yikang H. (2007), “Control strategy of an active crowbar for dfig
based wind turbine under grid voltage dips”, International Conference on
[69] Peresada S., Tilli A., and Tonielli A. (2004), “Power control of a doubly fed
induction machine via output feedback”, Control Engineering Practice, 12, pp.
41-57.
[70] Petersson A., Harnefors L., and Thiringer T. (2004), “Comparison between stator-flux and grid-flux-oriented rotor current control of doubly-fed induction
generators”, IEEE 35th Annual Power Electronics Specialists Conference, PESC
04, 1, pp. 482 - 486.
[71] Pierik J. T. G., Zhou Y., and Bauer P. (2007), Windfarm as Power Plant – Dynamic
Modelling Studies, Delft University Press.
[72] N. P. Quang, Dittrich A., and Thieme A. (1997), “Doubly-fed induction machine
as generator: control algorithms with decoupling of torque and power factor”,
Electrical Engineering (Archiv fur Elektrotechnik), 80, pp. 325 - 335.
[73] Nguyen Phung Quang, Dittrich A., and Phung Ngoc Lan (2005), “Doubly-fed induction machine as generator in wind power plant: nonlinear control algorithms
with direct decoupling”, European Conference on Power Electronics and
Applications.
[74] Nguyen Phung Quang, and Dittrich J.A. (2008), Vector Control of Three-Phase
AC Machines System Development in the Practice, Springer Berlin Heidelberg.
[75] Ramos C. J., Martins A. P., Araujo A. S., and Carvalho A. S. (2002), “Current control in the grid connection of the double-output induction generator linked to a
variable speed wind turbine”. 28th Annual Conference of the Industrial
[76] Rodriguez P., Teodorescu R., Timbus A. V., Liserre M., and Blaabjerg F. (2007), “Flexible active power control of distributed power generation systems during grid faults”, IEEE Transactions on Industrial Electronics, 54, pp. 2583 -2592.
[77] Rodriquez M., Abad G., Sarasola I., and Gilabert A. (2005), “Crowbar control
algorithms for doubly fed induction generator during voltage dips”, European
Conference on Power Electronics and Applications.
[78] Rolf Ottersten (2003), On Control of Back-to-Back Converters and Sensorless
Induction Machine Drives, PhD thesis, Chalmers University of Technology.
[79] Scherer C. W., Nguyen Tien Hung, and Scherpen J. M. A. (2007), “Self-scheduled
LPV controller synthesis for doubly-fed induction generators”, Windpower 2007
conference and Exhibition, USA, CDROM. (adsbygoogle = window.adsbygoogle || []).push({});
[80] Shen B., Mwinyiwiwa B., Zhang Y., Ooi B.T. (2009), “Sensorless maximum power point tracking of wind by dfig using rotor position phase lock loop” (pll),
IEEE Transactions on Power Electronics, 24, pp. 942 - 951.
[81] Stankovic A.V., and Lipo T.A. (2000), “A novel control method for input output harmonic elimination of the pwm boost type rectifier under unbalanced operating
conditions”, Applied Power Electronics Conference and Exposition, 1, pp. 413 -
419.
[82] Sun T., Chen Z., and Blaabjerg F. (2004), “Voltage recovery of grid-connected wind turbines with dfig after a short-circuit fault”, Power Electronics Specialists Conference, PESC, 3, pp. 1991 - 1997.
[83] Tang Y., and Xu L. (1995), “A flexible active and reactive power control strategy
for avariable speed constant frequency generating system”, IEEE Transactions on
Power Electronics, 10, pp. 472 - 478.
[84] Thiringer T., Petersson A., Harnefors L. (2005), “Evaluation of current control
methods for wind turbines using doubly fed induction machines”, IEEE
transactions on Power Electronics, 20, pp. 227 - 235.
[85] Toliyat H. A., and Campbell S. (2004), DSP-Based electromechanical motion
control, volume 3, CRC Press.
[86] Trzynadlowski A. M. (1994), The Field Orientation Principle in Control of
Induction Motors, Springer.
[87] Phan Van Tung, Hong – Hee Lee, and Chun Tae-Won (2010), “An improved control strategy using a PI- resonant controller for an unbalanced stand-alone
doubly-fed induction generator”, Journal of Power Electronics SCIE, 10(2), pp.
194 -202.
[88] Vechiu I., Camblong H., Tapia G., Dakyo B., and Curea O. (2007), “Control of four leg inverter for hybrid power system applications with unbalanced load”,
Energy Conversion and Management, 48, pp. 2119–2128.
[89] Xie B., Fox B., and Flynn D. (2004), Study of fault ride-through for dfig based
wind turbines. Electric Utility Deregulation, Restructuring and Power
Technologies conference, 1, pp. 411 - 416.
[90] Yamamoto M., and Motoyoshi O. (1991), “Active and reactive power control for
double-fed wound rotorinduction generator”, IEEE Transactions on Power
[91] Yi Zhou, Bauer P., Ferreira J. A., and Pierik J. (2009), “Operation of
grid-connected dfig under unbalanced grid voltage condition”, IEEE transactions