이 논문에서는 기상관측소의 기온 및 강수 관측치를 이용한 공간적 분포도 작성에 수치표고모델(DEM)과 다변량크리깅의 적용 가능성을 검토하였다. 기온 및 강수와 상관성을 가지면서 연구지역의 모든 지점에서 값을 제공하는 고도자료를 분포도 작성에 이용함으로써, 미관측 지점에서의 정보 부재 효과를 완화하면서 지형효과를 잘 반영하는 분포도를 작성하고자 하였다. 제주도 지역의 2005년 1월, 4월, 8월 및 10월의 월평균기온 및 월강수량 분포도 작성 사례 연구를 통해, 고도자료를 공동 크리깅에 의해 통합하였을 때 평활화 효과를 완화하면서 지형효과를 잘 반영하는 기온 및 강수 분포도 작성이 가능하였다. 또한 단변량 지구통계 기법인 정규 크리깅과 비교하였을 때, 보다 향상된 예측 능력을 나타내었다. 부가적으로 고도자료와의 상관성이 높을수록, 상대적 너겟 효과가 적을수록 예측 능력이 향상됨을 확인할 수 있었다.
이 논문에서는 기상관측소의 기온 및 강수 관측치를 이용한 공간적 분포도 작성에 수치표고모델(DEM)과 다변량 크리깅의 적용 가능성을 검토하였다. 기온 및 강수와 상관성을 가지면서 연구지역의 모든 지점에서 값을 제공하는 고도자료를 분포도 작성에 이용함으로써, 미관측 지점에서의 정보 부재 효과를 완화하면서 지형효과를 잘 반영하는 분포도를 작성하고자 하였다. 제주도 지역의 2005년 1월, 4월, 8월 및 10월의 월평균기온 및 월강수량 분포도 작성 사례 연구를 통해, 고도자료를 공동 크리깅에 의해 통합하였을 때 평활화 효과를 완화하면서 지형효과를 잘 반영하는 기온 및 강수 분포도 작성이 가능하였다. 또한 단변량 지구통계 기법인 정규 크리깅과 비교하였을 때, 보다 향상된 예측 능력을 나타내었다. 부가적으로 고도자료와의 상관성이 높을수록, 상대적 너겟 효과가 적을수록 예측 능력이 향상됨을 확인할 수 있었다.
We investigate the potential of digital elevation model and multivariate geostatistical kriging in mapping of temperature and rainfall based on sparse weather station observations. By using elevation data which have reasonable correlation with temperature and rainfall, and are exhaustively sampled i...
We investigate the potential of digital elevation model and multivariate geostatistical kriging in mapping of temperature and rainfall based on sparse weather station observations. By using elevation data which have reasonable correlation with temperature and rainfall, and are exhaustively sampled in the study area, we try to generate spatial distributions of temperature and rainfall which well reflect topographic effects and have less smoothing effects. To illustrate the applicability of this approach, we carried out a case study of Jeju island using observation data acquired in January, April, August, and October, 2005. From the case study results, accounting for elevation via colocated cokriging could reflect detailed topographic characteristics in the study area with less smoothing effects. Colocated cokriging also showed much improved prediction capability, compared to that of traditional univariate ordinary kriging. According to the increase of the magnitude of correlation between temperature or rainfall and elevation, much improved prediction capability could be obtained. The decrease of relative nugget effects also resulted in the improvement of prediction capability.
We investigate the potential of digital elevation model and multivariate geostatistical kriging in mapping of temperature and rainfall based on sparse weather station observations. By using elevation data which have reasonable correlation with temperature and rainfall, and are exhaustively sampled in the study area, we try to generate spatial distributions of temperature and rainfall which well reflect topographic effects and have less smoothing effects. To illustrate the applicability of this approach, we carried out a case study of Jeju island using observation data acquired in January, April, August, and October, 2005. From the case study results, accounting for elevation via colocated cokriging could reflect detailed topographic characteristics in the study area with less smoothing effects. Colocated cokriging also showed much improved prediction capability, compared to that of traditional univariate ordinary kriging. According to the increase of the magnitude of correlation between temperature or rainfall and elevation, much improved prediction capability could be obtained. The decrease of relative nugget effects also resulted in the improvement of prediction capability.
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