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The Influence of Rain Gauge Network Density on the Performance of a Hydrological Model
Autor: Andiego, G., Waseem, M., Usman, M., & Mani, N.
In:
Computational Water, Energy, and Environmental Engineering (CWEEE)
Bandangabe: 04
Auflage: 11
ISBN: ISSN Online: 2168- 1570, Print: 2168- 1562
DOI: 10.4236/cweee.2018.81002
Seite: 27 - 50
Jahr: 2017
Einordung:
Institut: Professur Wasserwirtschaft
Abstract:
Rain gauge data suffers from spatial errors because of precipitation variability within short distances and due to sparse or irregular network. Use of interpolation is often unreliable to evaluate due to the aforementioned irregular
sparse networks. This study is carried out in the Nette River catchment of Lower Saxony to alleviate the problem of using gauge data to measure the performance of interpolation. Radar precipitation data was extracted in the positions of 53 rain gauge stations, which are distributed throughout the range of the weather surveillance radar (WSR). Since radar data traditionally suffers from temporal errors, it was corrected using the Mean Field Bias (MFB) method by utilizing the rain gauge data and then further used as the reference precipitation in the study. The performances of Inverse Distance Weighting (IDW) and Ordinary Kriging (OK) interpolation methods by means of cross validation were assessed. Evaluation of the effect of the gauge densities on HBV-IWW hydrological model was achieved by comparing the simulated discharges for the two interpolation methods and corresponding densities against the simulated discharge of the reference precipitation data. Interpolation performance in winter was much better than summer for both interpolation methods. Furthermore, Ordinary Kriging performed marginally better than Inverse Distance Weighting in both seasons. In case of areal precipitation, progressive improvement in performance with increase in gauge density for both interpolation methods was observed, but Inverse Distance Weighting was found more consistent up to higher densities. Comparison
showed that Ordinary Kriging outperformed Inverse Distance Weighting only up to 70% density, beyond which the performance is equal. The hydrological modelling results are similar to that of are areal precipitation except that for both methods, there was no improvement in performance beyond the 50% gauge density. Ansprechpartner Weitere Information im WWW
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Letzte Änderung des Eintrages:
05.02.2018
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