This study made use of the data about days and amount of precipitation from 1906 to 1985 measured by the 34 local weather stations under the Korea Meteorological Service. Based on these data for eighty years, the probaility as well as intensity of precipitation of the probability of probability and intensity of precipitation was studied. The findings of this study are as follows The annual average probability of precipitation is 30.5%. 45.0% probability in July was the highest and 22.0% probability in October the lowest. The annual average intensity of precipitation was 10.5㎜/day. 18.0 ㎜/day in August was most intense and 4.4 ㎜/day in January and December least intense. Finally, the precipitation intensity from January to August increased gradually and decreased from August to December.

본 연구에서는 기상인자를 반영하여 확률강수량을 산정하고 불확실성을 평가하였다. 기상인자는 범지구적으로 관측되고 있는 해수면온도와 습윤지수 자료를 이용하였다. 분석 방법은 기상인자와 연최대시간강수량 사이의 지체상관계수를 산정하여 비교함으로써, 우리나라의 시간최대강수량과 상관관계가 큰 기상인자의 관측지역과 지체시간을 선정하고 지역가중다항식을 이용하여 회귀관계를 설정하였다. 다음으로 기상인자를 변동핵밀도함수를 이용하여 확률 밀도함수를 추정하여 모의발생을 수행

수공구조물의 설계를 위해서는 충분한 기간의 관측자료가 필요하지만, 우리나라의 수문자료는 대부분 충분한 수의 관측자료를 보유하고 있지 못하는 실정이다. 따라서 본 연구에서는 핵밀도함수를 이용한 비동질성 Markov 모형을 통해 시간강수량 자료를 모의하였다. 첫 번째로 시간강수량 자료에 변동핵밀도함수를 이용하여 천이확률을 산정하였으며, 두 번째로 난수와 천이확률을 통해 강수가 발생하는 시간을 결정하였다. 세 번째로 강수가 발생한 시간의 강수량의 크기를 핵밀

The characteristics on the transtion probabilities and periodicity for the daily precipitation occurrence in Korean peninsula are investigated by applying the Markov chain properties to daily precipitation occurrence. In order to examine the responses of Markov Chain properties to the applied period and their magnitudes, three cases (Case A: 1956∼1985 at 14 stations, Case B: 1965∼1994 at 14 stations, and Case C: 1985∼1994 at 63 stations) are considered in this study. The transition probabilities from wet day to wet day for all cases are about 0.50 and in summer, especially July, are higher. In addition, considering them in each station we can find that they are the highest at Ullung-do and lowest at Inchon for all cases. The annual equilibrium probabilities of a wet day appear 0.31 in Case A, 0.30 Case B, and 0.29 Case C, respectively. This may explain that as the data-period used becomes shorter, the higher the equilibrium probability is. The seasonal distributions of equilibrium probabilities are appeared the lowest(0.23∼0.28) in winter and the highest(more than 0.39) in spring and monthly in July and in October, repectively. The annual mean wet duration for all cases is 2.04 days in Case A, 1.99 Case B, and 1.89 Case C, repectively. The weather cycle obtained from the annual mean wet and dry duration is 6.54∼6.59 days, which are closely associated with the movement of synoptic systems. And the statistical tests show that the transitions of daily precipitation occurrence for all cases may have two-state first Markov chain property, being the stationarity in time and heterogeneity in space.