Abstract
Hydro-meteorological datasets are key components for understanding physical hydrological processes, but the scarcity of observational data hinders their potential application in poorly gauged regions. Satellite-retrieved and atmospheric reanalysis products exhibit considerable advantages in filling the spatial gaps in in-situ gauging networks and are thus forced to drive the physically lumped hydrological models for long-term streamflow simulation in data-sparse regions. As machine learning (ML)-based techniques can capture the relationship between different elements, they may have potential in further exploring meteorological predictors and hydrological responses. To examine the application prospects of a physically constrained ML algorithm using earth observation data, we used a short-series hydrological observation of the Hanjiang River basin in China as a case study. In this study, the prevalent modèle du Génie Rural à 9 paramètres Journalier (GR4J-9) hydrological model was used to initially simulate streamflow, and then, the simulated series and remote sensing data were used to train the long short-term memory (LSTM) method. The results demonstrated that the advanced GR4J9–LSTM model chain effectively improves the performance of the streamflow simulation by using more remote sensing data related to the hydrological response variables. Additionally, we derived a reservoir operation model by feeding the LSTM-based simulation outputs, which further revealed the potential application of our proposed technique.
Highlights
The availability of reliable hydro-meteorological material is an initial yet crucial part of water resource planning and management
With a hidden layer of 64 neurons and an initial learning rate of 0.1, the long short-term memory (LSTM)-based model could substantially improve the accuracy of the streamflow simulation compared to the GR4J-9 benchmark model
Hydro-meteorological data scarcity impairs hydrological simulation, manifesting a pressing need to develop an alternative scheme in this field
Summary
The availability of reliable hydro-meteorological material is an initial yet crucial part of water resource planning and management. Using hydrological simulation (or forecasting) as an example can have significant repercussions on socio-economic growth and development prospects from rainfall-runoff observations [1,2,3,4,5]. Obtaining access to actual long-series hydro-meteorological processes is worthy of further investigation. In recent decades, both satellite telemetry and data inversion techniques have been mined deeply, which compensate for the deficiencies of meteorological stations and provide. Sustainability 2021, 13, 3645 an attractive prospect for ungauged areas [6]. On the premise of controlling these open-source datasets (e.g., pilot balloon, unmanned aerial vehicle, and satellite), numerous studies have developed data assimilation techniques to further reconstruct long time-series historical climatic processes
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