• 대기
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• 제26권1호
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• pp.111-126
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• 2016

In the numerical weather model, surface properties can be defined by various parameters such as terrain height, landuse, surface albedo, soil moisture, surface emissivity, roughness length and so on. And these parameters need to be improved in the Seoul metropolitan area that established high-rise and complex buildings by urbanization at a recent time. The surface roughness length map is developed from digital elevation model (DEM) and it is implemented to the high-resolution numerical weather (WISE-WRF) model. Simulated results from WISE-WRF model are analyzed the relationship between meteorological variables to changes in the surface roughness length. Friction speed and wind speed are improved with various surface roughness in urban, these variables affected to temperature and relative humidity and hence the surface roughness length will affect to the precipitation and Planetary Boundary Layer (PBL) height. When surface variables by the WISE-WRF model are validated with Automatic Weather System (AWS) observations, NEW experiment is able to simulate more accurate than ORG experiment in temperature and wind speed. Especially, wind speed is overestimated over $2.5m\;s^{-1}$ on some AWS stations in Seoul and surrounding area but it improved with positive correlation and Root Mean Square Error (RMSE) below $2.5m\;s^{-1}$ in whole area. There are close relationship between surface roughness length and wind speed, and the change of surface variables lead to the change of location and duration of precipitation. As a result, the accuracy of WISE-WRF model is improved with the new surface roughness length retrieved from DEM, and its surface roughness length is important role in the high-resolution WISE-WRF model. By the way, the result in this study need various validation from retrieved the surface roughness length to numerical weather model simulations with observation data.

• 한국농림기상학회지
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• 제22권3호
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• pp.152-163
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• 2020

실제적인 산사태 대응조치 단계 이전에 산사태위험지수를 통하여 산사태 발생 위험도를 모니터링하고 예측하기 위하여, LAMP의 고해상도 강우와 토양수분 예측 자료를 DB화 하고, 산사태 연구자들의 연구대상 지역에 적합한 지도 투영법과 공간해상도로 변환하는 절차를 ArcGIS를 이용하여 마련하였다. 이를 위하여 ERA5 재분석 강수와 농촌진흥청 10m 깊이 토양수분자료를 이용하여 LAMP 모델 강수 및 토양수분 자료를 정량적 그리고 정성적으로 평가하여 모델의 특성을 파악하였다. 또한, LAMP 강우, 토양수분, 증발산 등의 결과 자료를 10m 초고해상도 ArcGIS 포맷 자료로 변환하는 과정을 실무적으로 상세히 기술하여, 국내 지역에서 WRF 모델의 NetCDF 자료를 ArcGIS로 이용자들이 손쉽게 변환할 수 있도록 기술적 편의를 제공하였다.