A novel dynamic closed-loop co-simulation methodology of overall wind turbine systems is presented in this thesis. This methodology consists of aerodynamics, mechanism dynamics, control system dynamics, and subsystem dynamics. Aerodynamic and turbine properties were modelled in FAST; ADAMS performed the mechanism dynamics; control system dynamics and subsystem dynamics such as generator, pitch control system and yaw control system were modeled and built in MATLAB/SIMULINK. Thus, this comprehensive integration of methodology expanded both the flexibility and controllability of wind turbine.. Besides, the dynamic simulation results were compared with the measuring results of SCADA (Supervisory Control and Data Acquisition) of a 2MW wind turbine for ensuring the novel dynamic co-simulation methodology. Besides, a novel hydrostatic speed control system with hydraulic pump-controlled pitch system and hydrostatic transmission system was also proposed in this study. To realize the hydrostatic speed-controlled wind turbine, a full-scale test rig of the hydraulic pitch control system of a 2MW wind turbine was developed for practically experimental verification. The pitch controller designed by two degree-of-freedom (2-DOF) motion controller with feedback linearization was developed to enhance the controllability and stability of the pitch control system. The wind turbine simulation software FAST was used to analyze the motion of the blade which results were given to the test rig as the disturbance load command. The robust 2-DOF pitch controller developed in this thesis contained a feedforward controller with feedback linearization theory to overcome the nonlinearities of the system and a feedback controller to improve the system robustness for achieving the disturbance rejection. Consequently, this thesis not only developed the wind turbine co-simulation methodology with high flexibility but also proposed and realized the novel robust hydraulic pitch control system by performing the excellent tracking performance of 5th order polynomial and sinusoidal path trajectory control in the experiments.