Calibration of Manning’s roughness coefficients for shallow-water flows on complex bathymetries using optimization algorithms and surrogate neural network models

•The main features of a newly developed high-performance multi-GPU solver for the shallow-water equations are presented. This solver is used to build a database of highfidelity solutions.•A surrogate model based on an ensemble of neural networks is trained on the database.•Optimization algorithms ar...

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Vydané v:Computers & fluids Ročník 304; s. 106884
Hlavní autori: Metcheka Kengne, Igor Gildas, Delmas, Vincent, Soulaïmani, Azzeddine
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier Ltd 15.01.2026
Predmet:
Calibration
CUDA
Ensemble model
Finite volumes
Manning roughness coefficient
Metaheuristic optimization algorithms
Multi-GPU
Neural networks
Shallow-water equations
Manning roughness coefficient
CUDA
Metaheuristic optimization algorithms
Ensemble model
Neural networks
Multi-GPU
Calibration
Finite volumes
Shallow-water equations
ISSN:0045-7930
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Popis
Shrnutí:•The main features of a newly developed high-performance multi-GPU solver for the shallow-water equations are presented. This solver is used to build a database of highfidelity solutions.•A surrogate model based on an ensemble of neural networks is trained on the database.•Optimization algorithms are analyzed to identify the optimal Manning friction coefficients using the surrogate model. Notably, no convergence issue is observed and accurate solutions are obtained.•Hybrid Particle Swarm Optimization (HPSO) algorithm revealed robust and fast convergence.•The versatility of this approach makes it applicable to various domains. This paper presents an effective methodology for the automatic calibration of Manning’s roughness coefficients, which are crucial parameters for modeling shallow free-surface flows. Traditionally determined through empirical methods, these coefficients are subject to significant variability, making their determination challenging, especially in flow areas with complex bathymetry. The conventional trial-and-error approach, widely used to select these coefficients, is often tedious and time-consuming, particularly in applications constrained by time and data availability. The proposed methodology aims to determine the optimal values of Manning’s coefficients distributed over the flow domain while minimizing global discrepancies between simulations and field measurements. The calibration approach is formulated as an inverse optimization problem and addressed using metaheuristic optimization algorithms such as the Genetic Algorithm or Particle Swarm Optimization, combined with an ensemble model of deep neural networks. The database for training the neural networks is obtained using a newly developed finite volume-based shallow-water equations solver, parallelized on multiple GPUs, to generate large datasets of solutions for machine learning purposes. The performance of this approach is evaluated through various flow scenarios. Compared to conventional techniques, this methodology stands out for its simplicity, computational efficiency, and robustness. Additionally, Hybrid Particle Swarm Optimization (HPSO) proves to be particularly effective, notably for its speed. The developed codes are available at: https://github.com/ETS-GRANIT/CuteFlow.
ISSN:0045-7930
DOI:10.1016/j.compfluid.2025.106884