Abstract

Floods, storms and hurricanes are devastating for human life and agricultural cropland. Near-real-time (NRT) discharge estimation is crucial to avoid the damages from flood disasters. The key input for the discharge estimation is precipitation. Directly using the ground stations to measure precipitation is not efficient, especially during a severe rainstorm, because precipitation varies even in the same region. This uncertainty might result in much less robust flood discharge estimation and forecasting models. The use of satellite precipitation products (SPPs) provides a larger area of coverage of rainstorms and a higher frequency of precipitation data compared to using the ground stations. In this paper, based on SPPs, a new NRT flood forecasting approach is proposed to reduce the time of the emergency response to flood disasters to minimize disaster damage. The proposed method allows us to forecast floods using a discharge hydrograph and to use the results to map flood extent by introducing SPPs into the rainfall–runoff model. In this study, we first evaluated the capacity of SPPs to estimate flood discharge and their accuracy in flood extent mapping. Two high temporal resolution SPPs were compared, integrated multi-satellite retrievals for global precipitation measurement (IMERG) and tropical rainfall measurement mission multi-satellite precipitation analysis (TMPA). The two products are evaluated over the Ottawa watershed in Canada during the period from 10 April 2017 to 10 May 2017. With TMPA, the results showed that the difference between the observed and modeled discharges was significant with a Nash–Sutcliffe efficiency (NSE) of −0.9241 and an adapted NSE (ANSE) of −1.0048 under high flow conditions. The TMPA-based model did not reproduce the shape of the observed hydrographs. However, with IMERG, the difference between the observed and modeled discharges was improved with an NSE equal to 0.80387 and an ANSE of 0.82874. Also, the IMERG-based model could reproduce the shape of the observed hydrographs, mainly under high flow conditions. Since IMERG products provide better accuracy, they were used for flood extent mapping in this study. Flood mapping results showed that the error was mostly within one pixel compared with the observed flood benchmark data of the Ottawa River acquired by RadarSat-2 during the flood event. The newly developed flood forecasting approach based on SPPs offers a solution for flood disaster management for poorly or totally ungauged watersheds regarding precipitation measurement. These findings could be referred to by others for NRT flood forecasting research and applications.

Highlights

  • Floods are one of the most devastating natural hazards in the world [1] and their forecast is essential in flood risk reduction and disaster response decisions [2]

  • With tropical rainfall measurement mission multi-satellite precipitation analysis (TMPA), the results showed that the difference between the observed and modeled discharges was significant with a Nash–Sutcliffe efficiency (NSE) of −0.9241 and an adapted NSE (ANSE) of −1.0048 under high flow conditions

  • With integrated multi-satellite retrievals for global precipitation measurement (IMERG) as input, values of NSE and ANSE are equal to −23.0073 and −21.7878, respectively, which reflects the significant difference between the modeled discharge and the observed discharge from the ground station

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Summary

Introduction

Floods are one of the most devastating natural hazards in the world [1] and their forecast is essential in flood risk reduction and disaster response decisions [2]. In spite of the considerable efforts in flood disaster management by national and international organizations, floods still have a negative impact on terrestrial environments. In this context, the most efficient tools for flood disaster reduction are needed to provide timely emergency responses in large-scale areas. The use of ground stations to directly measure precipitation might increase the uncertainties due to limited spatial distribution of ground stations so that the accuracy of flood discharge estimation and mapping would be affected. Space technologies have been developed to measure precipitation using satellites Due to their high temporal and spatial resolutions, satellite precipitation products (SPPs) have provided a new opportunity for flood discharge estimation

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