With the increasing integration of wind power into the power system, the incorporation of wind turbines into the grid's primary frequency regulation through inertia and droop control has been proven effective. However, a phenomenon known as secondary frequency dip (SFD) occurs when wind generators exit frequency regulation to restore the turbines’ speeds. This paper introduces a cooperative approach to mitigate SFD. Initially, a system frequency response model is established, incorporating the combined effects of synchronous generators and wind turbines. Subsequently, a model to forecast the rotational speed of each wind turbine in response to load changes is developed. Based on these models, the droop and inertia coefficients of different turbines in a wind farm are optimized to minimize overall wind energy loss during frequency regulation, thereby alleviating SFD, while ensuring the rotational speed remains within a safe range. Additionally, a smooth transition strategy based on a low-pass filter is proposed to prevent an abrupt decrease in active power as turbines exit frequency regulation. Finally, to prevent a simultaneous drop in active power among a large number of wind turbines, a sequential exit strategy from frequency regulation is proposed. Simulation results validate the effectiveness of the proposed methods in mitigating SFD.