Statistical downscaling methods are widely used to downscale the outputs of General Circulation Models (GCMs). However, the statistical downscaling methods tend to underestimate, especially the extreme values. To solve this problem, a new statistical downscaling method based on rainfall patterns is proposed in this study. Daily rainfall data from 12 rainfall stations in Taiwan are used. In addition, the large-scale weather factors obtained from NCEP/NCAR reanalysis project and GCMs runs are employed. The proposed method is used to assess the impacts of specific climate change scenarios on future rainfall. The proposed method is composed of two steps. The first step is daily rainfall classification step in which two classification models, extreme rainfall and wet rainfall, are established. These two models are used to identify the rainfall patterns (extreme rainfall, normal rainfall and dry rainfall) of the daily weather factors. The Detrended Fluctuation Analysis (DFA) is used to define the extreme rainfall. The classification models establish the relationship between NCEP/NCAR weather factors and rainfall patterns using Support Vector Machine (SVM). The second step is daily rainfall estimation step. Improved Self-Organizing Linear Output Map (ISOLO) is used to estimate the rainfall amounts for three different rainfall patterns. The changes of downscaled rainfall based on the outputs of 20C3M and the projections of GCMs for A2 and B1 scenarios over the study area are investigated. The results demonstrate that the proposed method provides reliable and accurate rainfall-pattern classification. In addition, the improvement of the estimation of daily rainfall series is significant, especially for the extreme rainfall. In conclusion, the proposed method is practical and suitable for the future projections.