Iván Couceiro scite author profile

In this work, a new discretization of the source term of the shallow water equations with non-flat bottom geometry is proposed to obtain a well-balanced scheme. A Smoothed Particle Hydrodynamics Arbitrary Lagrangian-Eulerian formulation based on Riemann solvers is presented to solve the SWE. Moving-Least Squares approximations are used to compute high-order reconstructions of the numerical fluxes and, stability is achieved using the a posteriori MOOD paradigm. Several benchmark 1D and 2D numerical problems are considered to test and validate the properties and behavior of the presented schemes.

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SPH-ALE Scheme for Weakly Compressible Viscous Flow with a Posteriori Stabilization

Eirís¹,

Ramírez²,

Fernández-Fidalgo³

et al. 2021

Water

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A highly accurate SPH method with a new stabilization paradigm has been introduced by the authors in a recent paper aimed to solve Euler equations for ideal gases. We present here the extension of the method to viscous incompressible flow. Incompressibility is tackled assuming a weakly compressible approach. The method adopts the SPH-ALE framework and improves accuracy by taking high-order variable reconstruction of the Riemann states at the midpoints between interacting particles. The moving least squares technique is used to estimate the derivatives required for the Taylor approximations for convective fluxes, and also provides the derivatives needed to discretize the viscous flux terms. Stability is preserved by implementing the a posteriori Multi-dimensional Optimal Order Detection (MOOD) method procedure thus avoiding the utilization of any slope/flux limiter or artificial viscosity. The capabilities of the method are illustrated by solving one- and two-dimensional Riemann problems and benchmark cases. The proposed methodology shows improvements in accuracy in the Riemann problems and does not require any parameter calibration. In addition, the method is extended to the solution of viscous flow and results are validated with the analytical Taylor–Green, Couette and Poiseuille flows, and lid-driven cavity test cases.

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Optimization of Offshore Steel Jackets: Review and Proposal of a New Formulation for Time-Dependent Constraints

Couceiro

París

Navarrina

et al. 2019

Arch Computat Methods Eng

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A new Mean Preserving Moving Least Squares method for Arbitrary Order Finite Volume schemes

Ramírez

Edreira

Couceiro

et al. 2023

Applied Mathematics and Computation

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Iván Couceiro

Structural optimization of lattice steel transmission towers

A Well-Balanced SPH-ALE Scheme for Shallow Water Applications

SPH-ALE Scheme for Weakly Compressible Viscous Flow with a Posteriori Stabilization

Optimization of Offshore Steel Jackets: Review and Proposal of a New Formulation for Time-Dependent Constraints

A new Mean Preserving Moving Least Squares method for Arbitrary Order Finite Volume schemes

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