Solar radiation is the primary driving force in global system. Downward Solar Irradiance (DSI) plays an important role in synoptic climate model, mesoscale evapotranspiration, and microscale canopy flux. Many studies tried to develop radiation models to compute DSI components on rugged terrain. However, little research has been done on the estimation of DSI over Taiwan. The purpose of this study is to estimate DSI and determine DSI distribution over the complex terrain of Taiwan. A model which based on satellite images and digital terrain data, called SDEM ( Satellite-based DSI Estimation Model), was developed. The SDEM includes the factors from astronomy, atmosphere, and terrain effects. The DSI estimation from SDEM comparing with minutely DSI measurement at RCEC Tainan and Taipei site showed the correlation coefficients were above 0.93 in clear sky cases and 0.80 in cloudy cases during 2006 to 2007. The validation of SDEM estimation with hourly accumulated measurement at 20 sites of Central Weather Bureau (CWB) showed the correlation coefficients were above 0.90 at the sites which are located in plain areas. Although the MTSAT visible band images provide inadequate evidences to detect fog in mountain region, the correlation coefficients of hourly accumulated value at CWB mountain sites were still above 0.8. The SDEM in this study only considers the MTSAT visible band images to compute the atmospheric effect. The results showed the parameters were unable to describe the detail of atmospheric properties. We expect IR-channel images used in SDEM to calculate the atmospheric effect could improve the estimation accuracy of DSI in the future.