Brahim Nait-kaci, Mamadou L. Doumbia, “Active and Reactive power control of a doubly fed induction generator for wind applications”, IEEE 2009.
 Arantxa Tapia, Gerardo Tapia, J. Xabier Ostolaza, “Modeling and Control of a Wind Turbine Driven doubly fed Induction Generator”, IEEE 2003.
 J. Ben Alaya, A Khedher and M. F. Mimouni, "DTC, DPC and Nonlinear Vector Control Strategies Applied to the DFIG operated at Variable Speed", Journal of Electrical Engineering (IEEE), vol.6, no II, pp. 744-753, 2011.
 A. Nassani, A. Ghazal, and A L. Elshafei, "Speed sensorless control of DFIG based MRAS observer", 14th International Middle East Conference, pp. 476-481. 2010.
 A Luna, F. K. A Lima, P. Rodriguez, E. H. Watanabe and R. Teodorescu, "Comparison of Power Control Strategies for DFIG Wind Turbines", IEEE Trans on Energy Conversion, pp. 2131-2136, 2008.
 M. Singh, V. Khadkikar, A. Chandra. Grid synchronization with harmonics and reactive power compensation capability of a permanent magnet synchronous generator-based variable speed wind energy conversion system. IET Power Electronics 2011; 41:122e30.
 Z. Chen, Compensation schemes for a SCR converter in variable speed wind power systems. IEEE Transactions on Power Delivery 2004; 192:813e21.
 S. Engelhardt, I. Erlich, C. Feltes, J. Kretschmann, F. Shewarega. Reactive power capability of wind turbines based on doubly fed induction generators. IEEE Transactions on Energy Conversion 2011; 261:364e72.
 Kayikçi. M, J. Milanovic. Reactive power control strategies for DFIG-based plants. IEEE Transactions on Energy Conversion 2007; 222:389e96.
 M. Machmoum, A. Hatoum, T. Bouaouiche. Flicker mitigation of a doubly-fed induction generator for wind energy conversion system. Mathematics and Computers in Simulation 2010; 812:433e45.
 M. Shahbazi, P. Poore, S. Saadate, M.R Zalghadri. Five-leg converter topology for wind energy conversion system with doubly fed induction generator. Renewable Energy 2011; 3611:3187e94.
 O. Soares, H. Gonçalves, A. Martins, A. Carvalho. Nonlinear control of the doubly fed induction generator in wind power systems. Renewable Energy 2010; 358:1662e70.
 F. Poitiers, T. Bouaouiche, M. Machmoum. Advanced control of a doubly-fed induction generator for wind energy conversion. Electric Power Systems Research 2009; 797:1085e96.
 T.K.A. Brekken, N. Mohan. Control of a doubly fed induction wind generator under unbalanced grid voltage conditions. IEEE Transaction on Energy Conversion 22 (March (1)) (2007) 129–135.
 Z. S., Changliang Xia, T. Shi. Assessing transient response of DFIG based wind turbines during voltage dips regarding main flux saturation and rotor deep-bar effect. Applied Energy 87 (2010) 3283–3293.
 A. Gaillard, P. Poure, S. Saadate, M. Machmoum. Variable Speed DFIG Wind Energy System for Power Generation and Harmonic Current Mitigation. Renewable Energy 34, 2009 pp 1545-1553.
 B. Robyns, B. Francois, P. Degobert, J. P. Hautier, Vector control of induction machines, Springer-Verlag London 2012.
 P.C. Krause Analysis of electric machinery. New York: McGraw-Hill; 1986.
 H. M. Jabr and N. C. Kar, “Neuro-fuzzy vector control for doubly-fed wind driven induction generator,” in Proc. of the IEEE Electrical Power Conference, pp. 236 - 241, 2007.
 H. M. Jabr and N. C. Kar, “Leakage flux saturation effects on the transient performance of wound-rotor induction motor,” Journal of Electric Power Systems Research, Vol.78, No.7, pp.1280-1289, 2008.