With improvement in variable speed system control and design of wind power system, the energy capture of these systems also rising. For enhance the efficiency and performance of wind energy conversion system(WECS),In this paper come up with Pitch angle control of a Doubly FED Induction Generator(DFIG) based wind power system with the objective of maintain constant power with variable wind speed by using fuzzy logic controller. This paper presents principal conversion of wind energy, wind turbine linearization and dynamic modeling are derived.  The fuzzy logic controller is employed for change blade angle of wind turbine and constant power can be achieve. The block diagram of proposed pitch control which consists of pitch controller, actuator model and turbine linearized modeled by using Matlab/Simulink software.

Liuchen Chang “Wind Energy Conversion Systems”, IEEE Canadian Review - spring / Printemps, pp. 12- 16, 2010.

Abdel Aitouche and Elkhatib Kamal, “Intelligent Control of Wind Energy Conversion Systems”, ISBN: 978-953- 307-467-2, InTech, 2011.

Q. Wang and L. Chang, “An intelligent maximum power extraction algorithm for inverter-based variable speed wind turbine systems,” IEEE Trans. Power Electron., vol. 19, no. 5, pp. 1242-1249, Sept. 2004.

Boik, S.2003.Grid Requirements challenges for wind Turbines. Billund: Fourth International workshop on Large –scale Integration of wind power and Transmission Networks for Offshore Wind frame.

Slootweg, J.G., de Haan, S.W.H., Polinder, H., and Kling, W.L. 2003. General model for representing variable speed wind turbines in power system dynamics simulations. IEEE Transactions on Power Systems, Vol.18, No.1, pp.144- 151.

Iov, F., Hansen, A. D., Sørensen, P., and Blaabjerg, F. 2004. Wind Turbine Blockset in Matlab/Simulink. Denmark: Aalborg University.

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 wind- energy generation. IEEE Proc.-Electr. Power Appl., Vol. 143, No. 3.

Mugica, M.S., Urkiola, A. M., Vidal, M. R., and Redondo, R. R. 2004. Comparison of Dynamic Space Models for Wind Turbine Grid Integration Studies. Portugal.

Akdag, S. A., and Guler, O. 2010. Comparison of Wind Turbine Power Cuve Models. Sousse, Tunisia: International Renewable Energy Congress.

Bharanikumar, R., Yazhini, A. C., and Kumar, A. N.2010. Modling and Simulation of Wind Turbine Driven Permanent Magnet Generator with New MPPT Algorithm. Asian Power Electronics Journal, vol. 4,No:2.

Melicio, R., Mendes, V. M. F., and Catalao, J. P. S. 2009.Computer Simulation of Wind Power System : Power Electronics and Transient Stability Analysis. Kyoto, Japan: International Conference on Power System Transent(IPST2009).

Dffey, C.K. 1988. Update of harmonic standard IEEE -519: IEEE Recommended Practices and Requirement for Harmonic control in Electric Power Systems. In Proc of IEEE :Petroleum and Chemical Industry Conference, pp.249-255.