Litcius/Paper detail

Improving global hydrological simulations through bias-correction and multi-model blending

Amulya Chevuturi, Maliko Tanguy, Katie Facer-Childs, Alberto Martínez-de la Torre, Sunita Sarkar, Stephan Thober, Luis Samaniego, Oldřich Rakovec, Matthias Kelbling, Edwin H. Sutanudjaja, Niko Wanders, Eleanor Blyth

2023Journal of Hydrology24 citationsDOIOpen Access PDF

Abstract

There is an immediate need to develop accurate and reliable global hydrological forecasts in light of the future vulnerability to hydrological hazards and water scarcity under a changing climate. As a part of the World Meteorological Organization’s (WMO) Global Hydrological Status and Outlook System (HydroSOS) initiative, we investigated different approaches to blending multi-model simulations for developing holistic operational global forecasts. The ULYSSES (mULti-model hYdrological SeaSonal prEdictionS system) dataset, to be published as “Global seasonal forecasts and reforecasts of river discharge and related hydrological variables ensemble from four state-of-the-art land surface and hydrological models” is used in this study. The first step for improving these forecasts is to investigate ways to improve the model simulations, as global models are not calibrated for local conditions. The analysis was performed over 119 different catchments worldwide for the baseline period of 1981–2019 for three variables: evapotranspiration, surface soil moisture and streamflow. This study evaluated blending approaches with a performance metric based (weighted) averaging of the multi-model simulations, using the catchment’s Kling-Gupta Efficiency (KGE) for the variable to define the weight. Hydrological model simulations were also bias-corrected to improve the multi-model blending output. Weighted blending in conjunction with bias-correction provided the best improvement in performance for the catchments investigated. Applying modelled weights during blending original simulations improved performance over ungauged catchments. The results indicate that there is potential to successfully and easily implement the bias-corrected weighted blending approach to improve operational forecasts globally. This work can be used to improve water resources management and hydrological hazard mitigation, especially in data-sparse regions.

Topics & Concepts

Environmental scienceEvapotranspirationStreamflowClimatologyClimate modelMeteorologyVariable (mathematics)Metric (unit)Water cycleHydrological modellingComputer scienceClimate changeHydrology (agriculture)Drainage basinMathematicsGeographyBiologyCartographyOperations managementGeotechnical engineeringEconomicsMathematical analysisGeologyEngineeringEcologyHydrology and Watershed Management StudiesFlood Risk Assessment and ManagementHydrological Forecasting Using AI