Simon Berkhahn scite author profile

Pluvial floods in urban areas are caused by local, fast storm events with very high rainfall rates, which lead to inundation of streets and buildings before the storm water reaches a watercourse. An increase in frequency and intensity of heavy rainfall events and an ongoing urbanization may further increase the risk of pluvial flooding in many urban areas. Currently, warnings for pluvial floods are mostly limited to information on rainfall intensities and durations over larger areas, which is often not detailed enough to effectively protect people and goods. We present a proof‐of‐concept for an impact‐based forecasting system for pluvial floods. Using a model chain consisting of a rainfall forecast, an inundation, a contaminant transport and a damage model, we are able to provide predictions for the expected rainfall, the inundated areas, spreading of potential contamination and the expected damage to residential buildings. We use a neural network‐based inundation model, which significantly reduces the computation time of the model chain. To demonstrate the feasibility, we perform a hindcast of a recent pluvial flood event in an urban area in Germany. The required spatio‐temporal accuracy of rainfall forecasts is still a major challenge, but our results show that reliable impact‐based warnings can be forecasts are available up to 5 min before the peak of an extreme rainfall event. Based on our results, we discuss how the outputs of the impact‐based forecast could be used to disseminate impact‐based early warnings.

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Real-Time Water Level Prediction Based on Artificial Neural Networks

Berkhahn

Neuweiler

Fuchs

2018

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Uncertainty of real-time prediction for pluvial urban floods: a case study

Berkhahn¹,

Sämann²,

Shehu³

et al. 2019

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Impact-based early warning for pluvial floods

Rözer¹,

Peche²,

Berkhahn³

et al. 2020

Preprint

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<p>Pluvial floods in urban areas are caused by local, fast storm events with very high rainfall rates, which lead to inundation of streets and buildings before the storm water reaches a watercourse.&#160; An increase in frequency and intensity of heavy rainfall events and an on-going urbanization may further increase the risk of pluvial flooding in many urban areas.&#160; Current early warning systems for pluvial floods are limited to rainfall predictions with fixed thresholds for rainfall duration and intensity and often do not provide the necessary information to effectively protect people and goods.&#160; We present a proof-of-concept for an impact-based early warning system for pluvial floods.&#160;</p><p>Using a model chain consisting of a rainfall forecast, an inundation, a contaminant transport and a damage model, we are able to provide predictions for the expected rainfall, the inundated areas, spreading of potential contamination and the expected damage to residential buildings. We use a neural network-based inundation model, which significantly reduces the computation time of the model chain.&#160; To demonstrate the feasibility, we perform a hindcast of a recent pluvial flood event in an urban area in Germany.&#160; The required spatio-temporal accuracy of rainfall forecasts is still a major challenge, but our results show that reliable impact-based warnings can be issued up to 5 minutes before the peak of an extreme rainfall event.&#160; To effectively disseminate the warnings issued by the model chain we propose a two-way mobile warning application that allows for the collection of real-time validation data.</p>

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Simon Berkhahn

An ensemble neural network model for real-time prediction of urban floods

Impact‐Based Forecasting for Pluvial Floods

Real-Time Water Level Prediction Based on Artificial Neural Networks

Uncertainty of real-time prediction for pluvial urban floods: a case study

Impact-based early warning for pluvial floods

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