BEIJING: Chinese scientists have recently proposed a novel artificial intelligence (AI)-based model to address streamflow and flood forecasting at a global scale for both gauged and ungauged catchments which remains one of the long-standing challenges in hydrology, given that more than 95 percent of small- and medium-sized watersheds worldwide do not have any monitoring data.
According to a report by Global Times, in the context of global climate change, there has been a notable rise in both the frequency and severity of extreme rainfall occurrences. This trend has resulted in more frequent occurrences of flooding disasters and heightened risks of flooding. Consequently, accurate prediction of flood discharge emerges as a pivotal element in mitigating the hazards associated with flood disasters.
Despite the significant progress that has been made in physical process-based flood discharge prediction over the past few decades, forecasting results using current methods still heavily rely on monitoring data and
parameter calibration.
Recent progress and expansion in deep learning have made AI technology-based data-driven models an alternatively novel solution for streamflow and flood forecasting in hydrological science.
A Chinese research team led by Ouyang Chaojun, a research fellow with the Institute of Mountain Hazards and Environment from the Chinese Academy of Sciences, proposed an AI-based novel streamflow and flood forecasting model to solve the streamflow and flood prediction problems at a global scale for both gauged and ungauged catchments.
Data-driven models are critically dependent on the quality of historical data. The research team is leveraging historical data sets across 2,089 catchments from the US, Canada, Central Europe, and the UK with a data collection frequency of 24 hours and the time span between 1st January, 1981, and 31st December, 2009, to train the model, while also using historical data sets between 1st January, 2010, and 1st January, 2012, to verify the accuracy of the model’s foreca
sting capability, Ouyang told the Global Times on Monday.
According to Ouyang, generally speaking, examining a longer period results in richer data sets, despite having higher training costs.
The significant diversity in the distribution of the data across these catchments ensures data variety and tests the accuracy and reliability of the model in the predictions for future time periods.
The verification results show that the model yields a mean Nash-Sutcliffe efficiency coefficient (NSE) of 0.75 – a commonly used score to assess the predictive power of hydrological discharge models – across 2,089 catchments, highlighting improvements by the state-of-the-art machine learning over traditional hydrologic models.
Based on the models pre-trained in the Northern Hemisphere, researchers conducted predictions on 160 entirely new river basins in Chile in the Southern Hemisphere without using any monitoring data, to test the model’s prediction ability in ungauged catchments. The prediction results of different pre
-trained models show strong spatial distribution consistency.
The model applied to 160 ungauged catchments in Chile shows 76.9 percent of catchments obtain NSE higher than zero in the best situation, demonstrating the potential of deep learning methods to overcome the ubiquitous lack of hydrologic information and deficiencies in physical model structure and parametrisation.
The model was recently published online through the interdisciplinary journal, The Innovation. This deep learning model can more effectively capture the spatial and physical attributes within the catchments.
Source: Emirates News Agency