Abstract
Flash floods occur frequently and distribute widely in mountainous areas because of complex geographic and geomorphic conditions and various climate types. Effective flash flood forecasting with useful lead times remains a challenge due to its high burstiness and short response time. Recently, machine learning has led to substantial changes across many areas of study. In hydrology, the advent of novel machine learning methods has started to encourage novel applications or substantially improve old ones. This study aims to establish a discharge forecasting model based on Long Short-Term Memory (LSTM) networks for flash flood forecasting in mountainous catchments. The proposed LSTM flood forecasting (LSTM-FF) model is composed of T multivariate single-step LSTM networks and takes spatial and temporal dynamics information of observed and forecast rainfall and early discharge as inputs. The case study in Anhe revealed that the proposed models can effectively predict flash floods, especially the qualified rates (the ratio of the number of qualified events to the total number of flood events) of large flood events are above 94.7% at 1–5 h lead time and range from 84.2% to 89.5% at 6–10 h lead-time. For the large flood simulation, the small flood events can help the LSTM-FF model to explore a better rainfall-runoff relationship. The impact analysis of weights in the LSTM network structures shows that the discharge input plays a more obvious role in the 1-h LSTM network and the effect decreases with the lead-time. Meanwhile, in the adjacent lead-time, the LSTM networks explored a similar relationship between input and output. The study provides a new approach for flash flood forecasting and the highly accurate forecast contributes to prepare for and mitigate disasters.
Highlights
Flash floods are among the most destructive natural disasters in many countries of the world and are characterized by widespread distribution, large quantities, and rapid occurrence
The impact analysis of weights in the Long Short-Term Memory (LSTM) network structures shows that the discharge input plays a more obvious role in the 1-h
Short lead time is largely attributed to the quick response of the rainfall-runoff relationship, which is impacted by complex geographic and geomorphic conditions and rainfall intensity and spatial-temporal distribution [2]
Summary
Flash floods are among the most destructive natural disasters in many countries of the world and are characterized by widespread distribution, large quantities, and rapid occurrence. 2015, China had an average of one hundred flash flood events which caused casualties each year [1]. Distinguished from regular floods, flash floods often occur in mountainous catchments of a few hundred square kilometers with a few hours of evacuation time. Short lead time is largely attributed to the quick response of the rainfall-runoff relationship, which is impacted by complex geographic and geomorphic conditions and rainfall intensity and spatial-temporal distribution [2]. Numerous catchments are facing a tough challenge of flash flood forecasting around the world [3]. Accurate and reliable short-term discharge forecasting is of great significance to preventing or mitigating a flash flood disaster
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