Ground-based velocity track display (GBVTD) technique has been proven to be effective on retrieving the kinematic structure of landfalling typhoons in Taiwan. However, significant errors are found due to the limitation of GBVTD technique especially when the environmental mean wind component perpendicular to the line connecting the radar and the typhoon center is large. A new iterative method, based on the velocity distance azimuth display (VDAD) technique proposed by Jou et al. (1996), has been developed to solve the environmental mean wind from the observed radial velocity data. In this thesis, an iterative method is designed for solving the environmental mean wind. This method is tested by setting up an experiment that an ideal Rankine vortex is embedded within a pre-assigned uniform mean wind environment. The results show that the error of retrieved mean wind speed is less than 1 m s-1 and the mean wind direction is less than 10°. These errors are sensitive to the distance between the vortex center and the radar, the noise of the data, the, the mean tangential wind speed, and the mean radial wind speed. The mean wind solver has been applied to a real typhoon case, Nock-Ten (2004). Using Hwa-Lien (HL) and Wu-Feng-Shan (WFS) radar data set respectively, the mean tangential wind component of Nock-Ten has been retrieved by original GBVTD method. It is found that the retrieved maximum mean tangential wind from HL is 14 m s-1 less than that solved by WFS data set. This large difference has been attributed to significant mean wind component perpendicular to the line connecting the radar and the typhoon center. After applying the newly developed mean wind solver to the data set, the difference of the retrieved maximum mean tangential wind has been reduced to 1.2 m s-1 which is significantly less than what was calculated originally. The importance of the mean wind solver is also demonstrated by discussing the mean vertical wind shear on precipitation distribution and the possible influence on the track of the storm while it is very close to the Taiwan topography.