Reactive power control strategy and rotor current regulator design for a wind farm with a doubly fed induction generator (DFIG) are investigated. To examine the effect of Idr on stator reactive power Qs and rotor reactive power Qr, the DFIG is operated under six different operating modes, i.e, the maximum Qs absorption mode, the rotor unity power factor mode, the minimum converter loss mode, the minimum copper loss mode, the stator unity power factor mode, and the maximum Qs generation mode with three models. The analytical results can be solved by the simplified model A and the simplified model B. The exact results can be solved by the complete model C. Maximum power tracking of a DFIG can be achieved through the control of rotor currents. A sliding mode regulator (SMR) is presented to regulate the rotor currents of a DFIG. The robustness to parameter variations can be accomplished by the proposed SMR when the wind turbine is subject to changing wind speed. Simulation results of a DFIG system with a 2.5MW generator are provided. To demonstrate the effectiveness of the proposed iterative algorithm, the rotor current, rotor voltage, stator current, real power and reactive power of a DFIG operated under the six different operating modes are computed. It is observed from the simulation results that the dynamic responses achieved by the proposed SMR are more robust than those by the fixed-gain PI regulator. The chattering effect caused by the switching function of the SMR can be reduced by an integral type sliding mode regulator (ISMR).