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Traditional sediment transport models are … Traditional sediment transport models are constrained by their spatial and/or temporal resolution, requiring high computational power and consuming extensive processing time. This limitation poses a substantial challenge in modeling two-dimensional landscape evolution over long-term scales and in predicting the impacts of system dynamics, such as climate change. To address this shortcoming, we introduce a novel Deep Learning (DL) framework that integrates Convolutional Neural Networks (CNN) with Long Short-Term Memory (LSTM) to capture the spatiotemporal morphodynamics of rivers in response to flooding events. This framework combines three models to simulate essential hydrodynamic and morphodynamic features: water depth, flow velocity, and bed change, which operate in a continuous loop to ensure dynamic updates to bed topography. The proposed framework was trained and evaluated using a dataset generated by HEC-RAS, a physics-based model, for a 22 km segment of Ninnescah River in Kansas. The hydrodynamic results demonstrate proficiency in capturing the flood dynamics, where the average Root Mean Square Error (RMSE) across the testing dataset is 0.19 m and 0.04 m/s for water depth and flow velocity, respectively. These hydrodynamic features are essential for the bed-change model, which exhibits high accuracy with a normalized RMSE and an R2 of 27% and 0.93, respectively, at the end of the testing dataset. Furthermore, the trained framework can generate predictions 4700 times faster than HEC-RAS. This work signifies a paradigm shift in the long-term simulation of river evolution and sets the stage for exploring new frontiers in fluvial morphodynamic modeling.ontiers in fluvial morphodynamic modeling. +
Accelerate Bed-Change Simulations Using Spatiotemporal Deep Learning Framework +
Fort Myers +
United States +
m.fathi.said0@gmail.com +
Mohamed Fathi +
Florida Gulf Coast University +
Said +
4845819234 +
Image: +
4) Get lazy with LLMs +
2) From Exploration to Publication: Geospatial Research in the Jupyter Ecosystem +
4) Integrating CNN with LSTM Models for Capturing Spatiotemporal Dynamics of Flood Modeling +
Florida +
United States +
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14:56:07, 8 February 2025 +
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17:09:31, 22 March 2025 +
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