Internal boundary conditions for a GPU-accelerated 2D shallow water model: Implementation and applications

•Internal boundary conditions are implemented in a GPU-enhanced 2D shallow water code.•Bridges and other types of structures can be included in the simulations.•The model is validated against experimental data and field observations.•The model is efficient and suitable for field-scale simulations. F...

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Bibliographic Details
Published in:Advances in water resources 2020-03, Vol.137, p.103525, Article 103525
Main Authors: Dazzi, Susanna, Vacondio, Renato, Mignosa, Paolo
Format: Article
Language:English
Subjects:
2D shallow water equations
Bridges
Flood modeling
GPU
Hydraulic structures
Internal boundary conditions
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Summary:•Internal boundary conditions are implemented in a GPU-enhanced 2D shallow water code.•Bridges and other types of structures can be included in the simulations.•The model is validated against experimental data and field observations.•The model is efficient and suitable for field-scale simulations. Flood propagation in rivers is strongly influenced by the presence of bridges and other hydraulic structures. Among the available approaches for including these elements in numerical models, the adoption of Internal Boundary Conditions (IBC), given its ability to capture backwater, is suitable for field-scale analyses for flood hazard assessment. In this paper, the implementation of internal boundary conditions in the two-dimensional shallow water code named “PARFLOOD” is presented. The application to experimental and real test cases shows that the proposed IBC model can handle both low and high flow conditions for bridges, while being flexible for other types of structures (e.g. flow-through dams). Moreover, the model is computationally efficient (physical/computational time ratio around 20–30 for domains with ~106 cells), thanks to the code parallelization on GPU.
ISSN:0309-1708
1872-9657
DOI:10.1016/j.advwatres.2020.103525