Solar radiation components reflected by the sea surface ($R_{ss}uparrow$) are additional energy sources comprising the solar radiation regime. Previous studies, based on observational approaches, indicated that $R_{ss}uparrow$ is an available climatological resource. However, an estimation process for $R_{ss}uparrow$ has not been established. In this case study over Jeju Island in South Korea, we applied a new estimation process to solar radiation modeling and discussed the spatial distribution of $R_{ss}uparrow$ and its seasonal variation. Our results showed that the illuminated area and the intensity of $R_{ss}uparrow$ became greatest at the winter solstice and least at the summer solstice. We estimated the illuminated area of $R_{ss}uparrow$ as it expanded over the southern slope of Jeju Island. At the winter solstice, on a daily basis, the area and intensity of illumination by $R_{ss}uparrow$ were $182.3km^2$ and $0.41;MJ;m^{-2};day;{-1}$, respectively. Comparing the daily accumulative and instantaneous values of $R_{ss}uparrow$ intensity, the difference was about 20 times greater in daily cases than in instantaneous cases. On the other hand, for instantaneous values, the $R_{ss}uparrow$ intensity accounted for up to 33% of the three components, i.e., direct, diffuse and reflected radiation in winter solstice. In addition, it was estimated that the sea surface reflectance depended on the wind speed. Therefore, in a practical use of this revised model, wind conditions should be considered as a critical factor in estimating $R_{ss}uparrow$.