Deep learning techniques for forecasting compound coastal flooding due to tropical cyclones

Master Thesis (2025)
Author(s)

D.H.H. Oudenes (TU Delft - Civil Engineering & Geosciences)

Contributor(s)

José A.A. Antolinez – Mentor (TU Delft - Coastal Engineering)

R. Gelderloos – Graduation committee member (TU Delft - Environmental Fluid Mechanics)

Alexander Heinlein – Graduation committee member (TU Delft - Numerical Analysis)

P. Athanasiou – Graduation committee member (Deltares)

P.A.K. van Asselt – Graduation committee member (Deltares)

Kees Nederhoff – Graduation committee member (Deltares-USA)

Faculty
Civil Engineering & Geosciences
More Info
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Publication Year
2025
Language
English
Graduation Date
25-06-2025
Awarding Institution
Delft University of Technology
Programme
['Civil Engineering | Hydraulic Engineering']
Faculty
Civil Engineering & Geosciences
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Abstract

Accurate flood prediction is essential for effective risk management, but simulating with physics-based models is computationally intensive and time-consuming, limiting their use in operational use cases. To address this challenge, this study develops a deep learning surrogate model that replicates spatial flood depth predictions of the physics-based model SFINCS, with significantly reduced computational cost.

The surrogate model is trained with a synthetic dataset of 13,000 tracks generated by TCWiSE, that have been computed with SFINCS. Input for the surrogate model are key drivers of compound coastal flooding, including cumulative precipitation, maximum wind speed, and water depth at the river outlet, which are given to the model as scalar values. The results demonstrate that the model can reproduce flood depth patterns with a RMSE of 0.054 m on the original dataset and 0.069 m on a case study application. The CSI values of 0.829 and 0.776, respectively, are comparable to values reported in recent literature. Visual inspection of spatial predictions shows that the model performs well overall but shows localized error patterns, particularly in the western part of the domain, indicating that additional input features may be needed to better capture interactions in physical processes that occur in compound coastal flooding. From a computational perspective, the deep learning model runs approximately 100 times faster than the physics-based model SFINCS on CPU, with further gains on GPU. This computational efficiency allows for running more simulations within a given timeframe, enabling the exploration of an increased number of potential flood scenarios and providing decision-makers with more time to evaluate and respond.

Overall, the study demonstrates that deep learning surrogate models offer a promising alternative to physics-based models by providing accurate and faster predictions. Although the current set-up shows accurate results, there remains room for improvement through enhanced input representation, such as incorporating spatiotemporal information of the drivers or including additional hydrodynamic features. Further gains in performance and generalizability can also be achieved by refining the model architecture and training strategies.

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