TY - JOUR
T1 - Effect of grid size on effective parameters and model performance of the MIKE-SHE code
AU - Vázquez, R.F.
AU - Feyen, L.
AU - Feyen, J.
AU - Refsgaard, J.C.
PY - 2002/2/15
Y1 - 2002/2/15
N2 - The present study discusses the application of the physically based distributed MIKE-SHE code to a medium size catchment using different grid sizes to investigate scale effects on the model results. First a 600 m grid-square model was calibrated. This was then subjected to a multi-resolution (MR) validation test by using the effective parameters of the calibrated model in a 300 m and a 1200 m grid-square model. The MR test indicated that the models for the resolutions analysed only differ marginally. Secondly, the effect of grid size on both the calibrated effective model parameters and the model performance was analysed in the scope of a multi-calibration test in which the calibration and validation processes were kept as unique and standard as possible for every grid size. The model was calibrated and validated for every grid size against both daily catchment discharge measurements and observed water levels using both a split sample procedure and a multi-site validation test. The investigation indicated that the best validation results, in terms of river discharge, were obtained with a 600 m grid-resolution, independent of the stream-flow station. This, together with the exponential increase in computation time when reducing the grid size, indicates that, for the given level of data input and quality, the model type and structure, and the time step, a 600 m grid-resolution is most appropriate for the catchment under study.
AB - The present study discusses the application of the physically based distributed MIKE-SHE code to a medium size catchment using different grid sizes to investigate scale effects on the model results. First a 600 m grid-square model was calibrated. This was then subjected to a multi-resolution (MR) validation test by using the effective parameters of the calibrated model in a 300 m and a 1200 m grid-square model. The MR test indicated that the models for the resolutions analysed only differ marginally. Secondly, the effect of grid size on both the calibrated effective model parameters and the model performance was analysed in the scope of a multi-calibration test in which the calibration and validation processes were kept as unique and standard as possible for every grid size. The model was calibrated and validated for every grid size against both daily catchment discharge measurements and observed water levels using both a split sample procedure and a multi-site validation test. The investigation indicated that the best validation results, in terms of river discharge, were obtained with a 600 m grid-resolution, independent of the stream-flow station. This, together with the exponential increase in computation time when reducing the grid size, indicates that, for the given level of data input and quality, the model type and structure, and the time step, a 600 m grid-resolution is most appropriate for the catchment under study.
KW - Distributed modelling
KW - Effective parameters
KW - Grid size
KW - MIKE-SHE
KW - Performance
UR - http://www.scopus.com/inward/record.url?scp=0037083411&partnerID=8YFLogxK
U2 - 10.1002/hyp.334
DO - 10.1002/hyp.334
M3 - Article
SN - 0885-6087
VL - 16
SP - 355
EP - 372
JO - Hydrological Processes
JF - Hydrological Processes
IS - 2
ER -