Pre-harvest sprouting (PHS) is defined as the germination of physiologically mature seeds on the mother plant before harvest. In the case of Taiwan, during the rainy season in May and June, the lodging of rice plants due to temporary heavy rains are the major causes of PHS at the end of the first crop season, resulting in reduced rice production and rice quality. Improving seed dormancy is a common breeding strategy to reduce PHS. However, strong dormancy seeds are not easy to germinate and show irregular germination in a short period of time after harvest, which is an unfavorable trait for rice seedling production in the second crop season in Taiwan. Moreover, it is not unusual that the observed PHS levels were significantly different for the same rice variety in different years. The ordinary method to evaluate the PHS level based on the germination percentage of freshly harvested rice seeds at the end of yellow ripe stage might be the cause of the discrepancy mentioned above. A study on wheat has shown that grains gained GA sensitivity and then lost ABA sensitivity during after-ripening (AR), the period of dry storage at room temperature for freshly harvested mature seeds. The changes in GA and ABA sensitivity was then used to serve as landmarks to define the level of seed dormancy and PHS. By adopting the strategy of the wheat study, we investigated the influences of exogenous GA and ABA application on the germination percentage of japonica rice in the preliminary experiment. The results showed that rice seeds also gained GA sensitivity and then lost ABA sensitivity during AR. In the following large-scale field experiment, we investigated the seed germination percentage of 219 japonica rice varieties, and selected 52 varieties with germination percentage less than 50%. Multiple comparison analysis testing for seed germination percentges measured from three different treatments: the freshly harvested seeds, AR14 seeds, and GA-treated AR14 seeds of each rice variety classified seed dormancy of the selected rice varieties into four groups. We also picked up three rice varieties that showed strong seed dormancy at the time freshly harvested but broke seed dormancy quickly. Besides, the small-scale repetitive trial in the greenhouse revealed that different cultivated environments greatly influence seed dormancy. These results can serve as a reference for the development of new methods to classify the level of seed dormancy in rice, as well as the information for selection of rice breeding materials for PHS.