An important advantage of radar observations is their high temporal and spatial resolutions, which are suitable for heavy weather surveillance. The purpose of this study is to improve the initial field and hence the quantitative precipitation forecast (QPF) of the numerical model by using multiple-Doppler radar observation data. The assimilation technique includes three components: multiple-Doppler radar wind synthesis, thermodynamic retrieval and moisture adjustment. A case during IOP8, Southwest Monsoon Experiment (SoWMEX) 2008 is selected in this study. The radar data in use are the reflectivity and radial wind of the RCCG and RCKT radars from CWB and the SPOL radar from NCAR at June 14, 2008. The 3-D winds, retrieved from the radar and sounding data, are utilized to calculate thermodynamic fields by the momentum equations. The moisture field is updated if some conditions, including a minimum reflectivity of 30 dBZ, occur. The numerical model in use is the Weather Research and Forecasting (WRF) model from NCAR. Some conclusions are made after a series of experiments: (1) A combination of Kain-Fritsch cumulus parameterization and WSM6 microphysics schemes gives the best result; (2) The moisture adjustment is necessary; (3) Both wind and thermodynamic retrieval algorithms consider the effect of snow; (4) Using multiple-Doppler radar data is necessary because a larger data coverage leads to better results. The above assimilation technique in this case significantly improves the accuracy of the forecast for at least 3 hours compared with the one without data assimilation in spite of overestimated precipitation. We expect applications of this technique to the cases of afternoon convection and even typhoons in the future.