Abstract
Streamflow prediction is a vital public service that helps to establish flash-flood early warning systems or assess the impact of projected climate change on water management. However, the availability of streamflow observations limits the utilization of the state-of-the-art streamflow prediction techniques to the basins where hydrometric gauging stations exist. Since the most river basins in the world are ungauged, the development of the specialized techniques for the reliable streamflow prediction in ungauged basins (PUB) is of crucial importance. In recent years, the emerging field of deep learning provides a myriad of new models that can breathe new life into the stagnating PUB methods. In the presented study, we benchmark the streamflow prediction efficiency of Long Short-Term Memory (LSTM) networks against the standard technique of GR4J hydrological model parameters regionalization (HMREG) at 200 basins in Northwest Russia. Results show that the LSTM-based regional hydrological model significantly outperforms the HMREG scheme in terms of median Nash-Sutcliffe efficiency (NSE), which is 0.73 and 0.61 for LSTM and HMREG, respectively. Moreover, LSTM demonstrates the comparable median NSE with that for basin-scale calibration of GR4J (0.75). Therefore, this study underlines the high utilization potential of deep learning for the PUB by demonstrating the new state-of-the-art performance in this field.
Highlights
Providing reliable streamflow predictions in ungauged basins (PUB) has crucial importance for understanding hydrological cycle processes where there are none or episodic hydrometric records [1]
It is a common practice in PUB studies that the basin-scale calibration results provide a so-called “superlative estimate,” i.e., show the best performance estimate that can be reachable in case of using the hydrological model for streamflow prediction
The obtained results confirm our previous study [17], where we showed that while model parameters regionalization technique based on spatial proximity provides reliable results for PUB, it cannot ensure uniform efficiency for a considerable portion of analyzed basins
Summary
Providing reliable streamflow predictions in ungauged basins (PUB) has crucial importance for understanding hydrological cycle processes where there are none or episodic hydrometric records [1]. The emerging field of deep learning has advanced many scientific disciplines, including hydrology [4]. Deep learning models, such as convolutional and recurrent neural networks, proved their ability to finding complex relationships in natural phenomena by utilizing the power of big data that is recently available in open domain [5]. The presented study aims to benchmark the prediction performance of deep learning for streamflow simulation in ungauged basins in comparison to standard and well-established technique of hydrological model parameters regionalization for 200 basins in Northwest Russia
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