• Journal of Korea Water Resources Association
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• v.40 no.7
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• pp.523-532
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• 2007

It has been operated since 1974, recently, the flood forecasting and warning system is applied in almost all the rivers in Korea, and the Storage Function Method (SFM) is used for flood routing. The SFM which was presented by Toshimitsu Kimura (1961) routes floods in channels and basins with the storage function as the basic equation. A watershed is divided into two zone, runoff and percolation area and runoff from runoff area is occurred when cumulated rainfall is not exceed saturation point, but exceed runoff is occurred from percolation area, too. Runoff area is given and not changed, runoff ratio is constant. In routing Process, runoff from runoff and percolation area is routed seperately with nonlinear conceptual reservoir having the same characteristics and it is unreasonable assumption. A modified SFM is proposed with storage function and continuity equation which has no assumption for routing process and effective rainfall is calculated by SCS Method. For Wi-stream, comparison of Kimura and the modified SFM is conducted, and it could be seen that the modified SFM is more improvable and applicable method easily by reducing the parameters.

• Proceedings of the Korea Water Resources Association Conference
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• 2007.05a
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• pp.449-453
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• 2007

Has been being operated since 1974, recently, the flood forecasting and warning system is applied in almost all the rivers in Korea, and the Storage Function Method(SFM) is used for flood routing. The SFM which was presented by Toshimitsu Kimura(1961) routes floods in channels and basins with the storage function as the basic equation. A watershed is devided into two zone, runoff and percolation area and Runoff is occured when cumulated rainfall is not exceed saturation rainfall, but exceed, runoff is occured from percolation area, too. Runoff area is given and not changed, runoff ratio is constant. In routing process, runoff from runoff and percolation area is routed seperately with nonlinear cenceptual reservior having same characteristics and it is unreasonable assumption. Modified SFM is proposed with storage function and continuity Equation which has no assumption for routing process and effective rainfall is calculated by SCS Method. For Wi Stream, comparision of Kimura and Modified SFM is conducted and It could be seen that Modified SFM is more improvemental and easily applicable method.

• Proceedings of the Korea Water Resources Association Conference
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• 2007.05a
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• pp.746-750
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• 2007

금강홍수통제소는 금강 유역의 홍수피해 경감을 목적으로 1990년 출범하였으며, 개소된 이래로 현재까지 홍수예보 및 수문 관측 업무를 수행하여 왔다. 금강홍수예보시스템의 유출모형은 이미 구축되어 있던 홍수예보 시스템과 마찬가지로 저류함수법과 단위도법에 의한 홍수 유출 모형을 근간으로 구성되어 있다. 최근 증설된 수문관측소를 반영하여 소유역을 재분할하고, 변화된 유역환경을 반영하여 저류함수모형에 대한 상수를 개선하고자 하였다. 소유역 및 하도분할과 티센계수 산정 등을 통해 저류함수법을 이용하기 위한 저류상수를 산정하기 위해 기존의 일반 종이지도로 제작된 지형도(1:50,000), 녹지자연도, 개략토양도 등을 이용하는 대신 수치지도를 이용하여 저류상수를 산정하였다. 새롭게 산정된 유역특성변수를 이용하여 유역의 저류상수를 산정하고 강우에 의한 유출량을 결정하였다. 변화된 유역 조건을 가지고 금강 유역의 전체 유역 및 하도유출계산을 수행한 후, 측정 결과가 있는 지점의 수문곡선과 비교하여 모형상수가 적절히 산정되었는지 검토하고, 개선된 모형상수를 제시하였다.

• Proceedings of the Korea Water Resources Association Conference
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• 2005.05b
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• pp.731-736
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• 2005

현재 국내 주요 하천의 홍수예경보시스템 운영과 다목적댐의 홍수조절관리를 위하여 수문학적 모형의 하나인 저류함수모형(Storage Function Model)을 사용하고 있다. 저류함수모형은 산지가 많은 유역에 적합하도록 개발된 모형으로, 계산절차가 간편하고 홍수유출의 비선형성을 고려할 수 있는 방법이므로 선형모형보다 합리적이라고 알려져 있다. 그러나 저류함수모형을 실제 홍수유출현상에 적용하는데 있어 매개변수를 결정하는 것이 매우 어렵다. 현재 매개변수들을 결정할 수 있는 객관적이고 합리적인 방법이 제시되어 있지 않기 때문에 모형의 매개변수를 결정할 때 경험식을 이용하거나 수문기술자의 판단에 의한 보정에 의존하고 있다. 따라서, 본 논문에서는 홍수통제소에서 사용하고 있는 저류함수 모형의 대표(평균) 매개변수와 경험식, 시행착오법(trial & error method) 및 최적화기법(optimization technique) 중에 Rosenbrock 방법을 이용하여 매개변수를 산정하고 이들을 비교 분석하고자 한다.

• Journal of the Korean Society of Hazard Mitigation
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• v.9 no.5
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• pp.125-130
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• 2009

Storage function method which considers the non-linearity of the relationship between rainfall and runoff has been frequently used to predict runoff in a basin and a flood pattern. However, it is time-consuming to estimate appropriate parameters of every basin and rainfall event, which requires the empirical parameter equation applicable in Korea. In this study, multiple regression analysis is used to develop empirical equations to estimate parameters of Storage Function method using basin characteristics. The basin area, maximum stream length, and stream slope are considered as the basin characteristics as the result of the regression analysis. Collinearity is removed and trial-and-error method is used to choose the most descriptive parameters to the dependent variables in Han River basin which is divided into 30 subbasins. The developed equations are validated using the rainfall events in MunMak gauging station and named as 'Han River equation'. The equation could provide the useful information about Storage Function method parameter to calculate runoff from a basin and predict river stage.

• Journal of Korea Water Resources Association
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• v.52 no.12
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• pp.1057-1066
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• 2019

The storage function method is used as a flood prediction model for four flood control offices in Korea as a method to analyze the actual rainfall-runoff relationship with non-linearity. It is essential to accurately estimate the parameters of the storage function method for accurate runoff analysis. However, the parameters of the storage function method currently in use are estimated by the empirical formula developed by the limited hydrological analysis in 2012; therefore, they are somewhat inaccurate. The kinematic wave method is a method based on physical variables of watershed and channel and is widely used for rainfall-runoff analysis. By adopting the two-term storage function method by the conversion of the kinematic wave method, parameters can be estimated based on physical variables, which can increase the accuracy of runoff calculation. In this research, the reproducibility of the kinematic wave method by the two-term storage function method was investigated. It is very easy to estimate the parameters because equivalent roughness, which is an important physical variable in watershed runoff, can be easily obtained by using land use and land cover, and the physical variable of channel runoff can be easily obtained from the basic river planning report or topographic map. In addition, this research examined the applicability of the two-term storage function method to runoff simulation of Naechon Stream, a tributary of the Hongcheon River in the Han River basin. As a result, it is considered that more accurate runoff calculation results could be obtained than the existing one-term storage function method. It is expected that the utilization of the storage function method can be increased because the parameters can be easily estimated using physical variables even in unmeasured watersheds and channels.

• Journal of the Korean Society of Hazard Mitigation
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• v.10 no.4
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• pp.95-104
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• 2010

The storage function model is one of the most commonly used models for flood forecasting and warning system in Korea. This paper studies the physical significance of the storage function model by comparing it with kinematic wave model. The results showed universal applicability of the storage function model to Korean basins. Through a comparison of the basic equations for the models, the storage function model parameters, K, P and $T_l$, are shown to be related with the kinematic wave model parameters, k and p. The analysis showed that P and p are identical and K and $T_l$ can be related to k, basin area, and coefficients of Hack's law. To apply the storage function model throughout the southern part of Korean peninsular, regional parameter relationships for K and $T_l$ were developed for watershed area using data from 17 watersheds and 101 flood events. These relationships combine the kinematic wave parameters with topographic information using Hack's Law.

• Journal of the Korean Society of Hazard Mitigation
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• v.10 no.6
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• pp.81-87
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• 2010

In order to calculate the accurate runoff from a basin, nonlinearity in the relationship between rainfall and runoff has to be considered. Many runoff calculation models assume the linearity in the relationship or are too complicated to be analyzed. Therefore, the storage function method has been used in the prediction of flood because of the simplicity of the model. The storage function method has five parameters with related to the basin and rainfall characteristics which can be estimated by the empirical trial and error method. To optimize these parameters, regression method or optimization techniques such as genetic algorithm have been used, however, it is not easy to optimize them because of the complexity of the method. In this study, the metamodel is proposed to estimate those model parameters. The metamodel is the combination of artificial neural network and genetic algorithm. The model is consisted of two stages. In the first stage, an artificial neural network is constructed using the given rainfall-runoff relationship. In the second stage, the parameters of the storage function method are estimated using genetic algorithm and the trained artificial neural network. The proposed metamodel is applied in the Peong Chang River basin and the results are presented.

• Proceedings of the Korea Water Resources Association Conference
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• 1998.05a
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• pp.62-67
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• 1998

낙동강 수계 다목적댐 하류 지역에 대한 홍수조절 의사결정 능력을 향상시키고자 강우- 유출 모형으로 선정된 저류함수법으로 낙동강 수계 다목적댐 하류부의 유역유출 체계를 먼저 구 성하였다. 저류함수법에 의한 낙동강 수계 유역유출 체계도는 유역의 물리적 특성을 감안하여 소 유역은 41개, 하동망은 28개로 구성하였다. 또한 수문학적 하도추적 기법이 갖는 결점을 보완하기 위하여 낙동강 본류 및 상류에 댐이 있는 금호강, 황강, 남강, 밀양강 등 1 지류 이상의 홍수추적 을 수리학적 모형으로 보완하여 유역유출 체계를 이원화하여 두시스템을 상호·연계할 수 있도록 하였다. 상기 두 시스템을 '93년 8월 홍수(8, 7~8, 15)에 시험 적용하였다. 모형수행 경과 홍수기 댐운영시 저류함수모형에 의한 강우 유출 모형과 수리학적 하도추적 모형을 통합한 시스템을 동시에 적용하여 상호 보완 과정을 통해 운영한다면 다목적댐의 홍수조절 의사결정능력을 향상시킬 수 있다고 판단된다. 본 연구에서는 사용자가 해석적 방법으로 유역에서 수문자료를 이용하여 매개변수를 대화식으로 산정할 수 있는 GUI 시스템을 EXCEL97 환경에서 개발하여 신뢰성 있는 Rating curve가 확보 상·하류에 위치한 12개 수위관측소에서 89개 홍수사상을 대상으로 유역의 매개변수를 산정하였다. 또한, 미계측 유역의 저류함수 관련 매개변수 확장을 위하여 12개 소유역 에 대한 매개변수의 평균값과 유역면적, 하도연장 및 경사, 유역의 사면경사 등의 지형인자들을 조합하여 지역화분석을 수행하여 미계측 유역의 매개변수 산정식으로 제안하였다. 본 회귀식으로 산정된 소유역별 매개변수를 '93년 8월 홍수(8, 7~8, 15)에 적용한 결과, 낙동강 수계 본류상 주요 수위관측소별 홍수량예측이 이근천공식 보다 양호한 결과를 주어 본 연구에서 제시한 유역의 매 개변수 회귀식은 미계측 유역의 매개변수 산정시 충분한 활용성을 입증하였다. 저류함수법에 의 한 낙동강 수계 다목적댐 하류부의 유역유출 체계도는 수리학적 하도추적 모형과의 연계와 유역 의 물리적 특성을 감안하여 현재의 홍수통제소에서 운영하는 홍수예경보 시스템의 유출체계도와 우리공사 물관리 상황실의 저수관리 모형의 유출체계도를 기준으로 재구성하여 다목적댐 하류부의 소유역은 41개, 하도망은 28개로 결정하였다.

• Magazine of the Korean Society of Agricultural Engineers
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• v.38 no.2
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• pp.75-86
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• 1996

The formulas for estimating the constants of storage function model including K and TL for runoff analysis and a distributed storage function model are discussed in this study. First, the relations between parameters of the storage function model and the kinematic runoff model are theoretically examined, and then optimum constants of storage function model are obtained by the Standardized Davidson-Fletcher-Powell (SDFP) method. Through this analysis, theoretical formulas were obtained as $K = 0.63 {\alpha} KsB{^0.6}$ and $T_{L}=0.11 {\alpha} KsB{^0.6} r{^0.4} {_e}$, which are difficult to use practically because of the unclarified definition of shape factors. From a practical point of view, empirical formula were derived as $K=15.6{^0.3} {_m}$ and $T_{L}=2.1B{^0.36} {_m} {_e}/r{^0.4} {_e}$ for applied watersheds. The proposed formulas are verified for several recoded floods at a few points of watersheds. It is also found that the distributed storage function. can be applied to flood runoff analysis using the new formulas aboved mentioned.