Climate change caused by the greenhouse effect and its related issues are becoming an increasing concern. The simulation results of general circulation models (GCMs) are an important basis for evaluating the impact of climate change on a river basin. However, the spatial scale of a GCM is generally much larger than a river basin. Therefore, a downscaling model is required to relate the GCM data to basin weather information before the GCM model can be applied to studying the impact of climate change on a basin scale problem. Conventional downscaling methods use a mathematical function to describe the data relation between large scales and basin scales. Although there is some degree of correlation between the data of these different scales, the relationship is highly uncertain and random. Instead of a deterministic function, a conditional probability distribution can better describe this scale relationship. Therefore, this study proposes a novel non-parametric statistic downscaling model (NPDM) to describe the scale relationship between selected large scale factors and basin rainfall using a non-parametric conditional probability distribution. This study also compares the NPDM performance with that of the statistical downscaling model (SDSM) through synthesis of basin rainfall. The results of this comparison show that, using the same large scale climate factors, the statistical parameters such as sample mean and standard deviation of the NPDM synthesis data is closer to the statistical parameters of observation data than those produced by the SDSM. This study demonstrates that the proposed novel NPDM is an appropriate downscaling model and its data can be used to investigate the impact of climate change on regional water resource management.