Mei-Yu season is one of the main rainy seasons in the Taiwan area. The prevailing southwest monsoon flow during this period frequently causes heavy rain events in the windward side of the southwestern Taiwan. In this study, the composited hybrid scan radar reflectivity data of the Central Weather Bureau (CWB)’s Quantitative Precipitation Estimation Segregation Using Multiple Sensors (QPESUMS) system and the lightning data of the Taiwan Power Company (Taipower)’s Total Lightning Detection System (TLDS) were used to examine the precipitation characteristics in southwestern Taiwan during the 2008 Mei-Yu season. In addition, the SoWMEX/ TiMREX field campaign provided high temporal resolution sounding data for documenting the environmental condition. The relations between the precipitation characteristics and their associated environment regimes were explored. A total of 40 rainfall events were identified in the 2008 Mei-Yu season. The results indicate that based on the initiation location, the precipitation events can be classified into three types: land, oceanic, and mixed. The former two types are evenly distributed (18:17) and occupy most of the cases. In terms of the time of development, the land events usually begin in the daytime with shorter durations. In contrast, the oceanic events have their initiations in the nighttime and persist longer. Most of the land events are related to the afternoon thunderstorms and reveal pronounced diurnal cycle signal. In terms of spatial distribution, on the average, the land-type precipitating systems are more concentrated with higher fraction of convective precipitation and higher lightning density while the oceanic types usually consist of widespread area of precipitation associated with larger fraction of stratiform. For the environmental conditions, the land events are associated with larger convective available potential energy (CAPE) and smaller convective inhibition (CIN), whereas the oceanic events are associated with smaller CAPE and higher CIN. Otherwise, the composited soundings show that the oceanic-type has a much stronger and moister southwesterly flow over the lower troposphere than land-type.