Abstract
Effective representation of precipitation inputs is one of the essential components in hydrological model structures, especially when gauge measurements for the modelled catchment are sparse. Assessment of the impact of precipitation pre-processing is often nontrivial as precipitation data are very limited in the first place. In this paper, we demonstrate a study using a semi-distributed hydrological model, the Soil and Water Assessment Tool (SWAT) to examine the impact of different precipitation pre-processing methods on model calibration and the overall model performance with regards to the operational use. A river catchment in the UK is modelled to test against the three pre-processing methods: the Centroid Point Estimation Method (CPEM), the Grid Area Method (GAM) and the Grid Point Method (GPM). Cross-calibration and validation are then carried out by using the high-resolution Centre for Ecology & Hydrology–Gridded Estimate Areal Rainfall (CEH-GEAR) dataset. The results show that the proposed methods GAM and GPM can improve the model calibration significantly against the one calibrated with the existing CPEM method used by the model; the performance differences in the validation among the calibrated models, however, remain small and become irrelevant. The findings indicate that it is preferable to always make use of high-quality rainfall data, when available, with a better pre-processing method, even with models that are previously calibrated with low-quality rainfall inputs. It is also shown that such improvements are affected by the size of catchment and become less significant for smaller catchments.
Highlights
Precipitation is one of the vital forcing factors in hydrological modelling processes
The Centre for Ecology and Hydrology (CEH)-Gridded Estimate Areal Rainfall (GEAR) dataset is derived from rain gauge observations with an extra quality control measure before being interpolated onto the regular grids
To measure the impacts of precipitation pre-processing on model calibrations, we calibrated the Soil and Water Assessment Tool (SWAT) models for the Dee catchment using the three pre-processing techniques centroid point estimate method (CPEM), Grid Area Method (GAM) and Grid Point Method (GPM) respectively
Summary
Precipitation is one of the vital forcing factors in hydrological modelling processes. The accuracy of precipitation as the input and its representation have a direct impact on the overall model performance. In the last few decades, many studies have been conducted with a focus on this, mainly due to the drive of quantifying modelling uncertainties, where inputs such as precipitation must be considered, for example [1,2]. Alongside the concerns of accuracy, the importance of spatial variability of rainfall has been highlighted, especially over large watersheds where it is crucial to gain insight of day-to-day spatial variability of groundwater level, streamflow discharge and soil moisture content [2]. Rainfall variability has a considerable impact on peak flow estimation [3]. It was reported in [4]
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