Evaluation of open-access global digital elevation models (AW3D30, SRTM and ASTER) for flood modelling purposes

This is a Preprint and has not been peer reviewed. The published version of this Preprint is available: https://doi.org/10.1111/jfr3.12550. This is version 1 of this Preprint.


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Laurent Courty, Julio César Soriano-Monzalvo, Adrián Pedrozo-Acuña


Digital Elevation Models (DEM) are a key piece of information for the accurate representation of topographic controls exerted in hydrologic and hydraulic models. Many practitioners rely on open-access global datasets usually obtained from space-borne survey due to the cost and sparse coverage of sources of higher resolution. In may 2016 the Japan Aerospace eXploration Agency publicly released an open-access global Digital Surface Model (DSM) at an horizontal resolution of 30m, the ALOS World 3D-30m (AW3D30). So far no published study did an in-depth assessment of the flood modelling capabilities of this new product.
The purpose of this investigation is to 1) present an assessment of the capacity of the AW3D30 for flood modelling purposes and 2) to compare its performance with regards to computed water levels and flood extent maps calculated using other freely available 30m DEM for model setup (e.g. SRTM and ASTER). For this comparison, the reference to reality is given by the water levels and flood extent maps computed with the same numerical model but using a 5m lidar based Digital Terrain Model re-sampled to 30m). The numerical model employed in this investigation is based on a damped partial inertia approximation of the Saint-Venant equations on a regular raster grid, which is forced with a simple and synthetic rainfall storm event.
Numerical results using different elevation data in model setup are compared for two regions with contrasting topographic gradients. Results with regards to water depth and flood extent show that AW3D30 performs better than the SRTM DEM. Notably, in the case of mountainous regions, the results derived with the AW3D30 are comparable in skill to those obtained with a lidar derived DSM, suggesting its suitability in the numerical reproduction of flood events. This encouraging performance paves the way to more accurate modelling for both data-scarce regions and global flood models.




Aerospace Engineering, Civil and Environmental Engineering, Computational Engineering, Computer Engineering, Earth Sciences, Engineering, Environmental Sciences, Hydraulic Engineering, Hydrology, Life Sciences, Physical Sciences and Mathematics, Water Resource Management



Published: 2018-06-25 11:37


CC BY Attribution 4.0 International

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