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- Title
On the Impacts of Observation Location, Timing, and Frequency on Flood Extent Assimilation Performance.
- Authors
Dasgupta, Antara; Hostache, Renaud; Ramsankaran, RAAJ; Schumann, Guy J.‐P.; Grimaldi, Stefania; Pauwels, Valentijn R. N.; Walker, Jeffrey P.
- Abstract
Flood inundation forecasts from hydrodynamic models can help with flood preparedness, but uncertainty in the inputs and parameters can lead to erroneous flood inundation estimates. However, Synthetic aperture radar (SAR)‐based flood extent information can be used to constrain such model forecasts through data assimilation thus making them more accurate. Since high‐resolution SAR satellites can only provide partial coverage for medium to large catchments, it is expedient to evaluate the combination of observation footprint, timing, and frequency which can lead to maximum forecast improvements. Consequently, multiple spatiotemporal SAR‐based flood extent assimilation scenarios have been simulated here to identify the optimum observation design for improved flood inundation forecasts. A mutual information‐based particle filter was implemented in a synthetic setup for the 2011 flood event in the Clarence Catchment, Australia, to combine SAR‐based flood extents with the hydraulic model LISFLOOD‐FP. The open loop ensemble was forced using uncertain inflows and the impact of assimilating flood extents in morphologically homogenous river reaches was evaluated for different first visit and revisit scenarios. Results revealed that the optimum temporal acquisition strategy strongly depends on reach morphology and flood wave arrival timing. Further, it was found that a single image at the right time could improve the 8‐days forecast by ∼95% when assimilated at reaches with large flat floodplains but limited tidal influence, while in reaches with narrow valleys over 10 images were needed to achieve the same outcome. Experiments such as the one presented here can therefore inform targeted observation strategies to ensure cost effective flood monitoring and maximize the forecast accuracy resulting from flood extent assimilation. Plain Language Summary: Satellite observations of flood inundation have the potential to increase the reliability and accuracy of flood forecasts, thereby contributing to improved flood resilience of vulnerable populations. However, new generation high‐resolution satellites can only observe small portions of large river systems river during a flood. Since, the model‐data integration methods used to combine flood forecasting models with satellite data are sensitive to the observation coverage, timing, and frequency best case scenarios can be constructed to obtain maximum improvements in accuracy. This study investigated the possibility of designing targeted observation strategies that can lead to more accurate flood forecasts after the model‐data integration. Synthetic experiments were used to simulate multiple different image acquisition scenarios and assess the impacts on flood forecast accuracy. Results indicate that the location and timing of the images is more important than the revisit interval. Findings from this study can therefore be used to inform future satellite acquisitions, to ensure more cost effective flood monitoring from space leading to more reliable flood inundation forecasts. Key Points: The potential of targeted observations for optimal flood inundation forecast improvements from flood extent assimilation is demonstratedImpact of assimilating images in morphologically uniform reaches at different times, on channel, and floodplain water depth quantifiedAssimilating a single ideal flood extent could lead to persistent improvements comparable to assimilating multiple sub‐optimal images
- Subjects
AUSTRALIA; FLOOD forecasting; SYNTHETIC aperture radar; WATERSHEDS; FLOODS; WATER depth
- Publication
Water Resources Research, 2021, Vol 57, Issue 2, p1
- ISSN
0043-1397
- Publication type
Article
- DOI
10.1029/2020WR028238