An upwind vertex centred finite volume algorithm for nearly and truly incompressible explicit fast solid dynamic applications: total and updated Lagrangian formulations
From MaRDI portal
Publication:6145378
DOI10.1016/j.jcpx.2019.100025MaRDI QIDQ6145378
Ataollah Ghavamian, Ferdinando Auricchio, Osama I. Hassan, Chun Hean Lee, Antonio J. Gil, Javier Bonet
Publication date: 9 January 2024
Published in: Journal of Computational Physics: X (Search for Journal in Brave)
Numerical and other methods in solid mechanics (74Sxx) Numerical methods for partial differential equations, initial value and time-dependent initial-boundary value problems (65Mxx) Elastic materials (74Bxx)
Cites Work
- Unnamed Item
- A vertex centred finite volume Jameson-Schmidt-Turkel (JST) algorithm for a mixed conservation formulation in solid dynamics
- A discontinuous Galerkin discretization for solving the two-dimensional gas dynamics equations written under total Lagrangian formulation on general unstructured grids
- Hybridizable discontinuous Galerkin methods for partial differential equations in continuum mechanics
- Discretization of hyperelasticity on unstructured mesh with a cell-centered Lagrangian scheme
- High order curvilinear finite elements for elastic-plastic Lagrangian dynamics
- Development of a stabilised Petrov-Galerkin formulation for conservation laws in Lagrangian fast solid dynamics
- A large strain finite volume method for orthotropic bodies with general material orientations
- A cell-centered Lagrangian hydrodynamics scheme on general unstructured meshes in arbitrary dimension
- A high-order cell-centered Lagrangian scheme for compressible fluid flows in two-dimensional cylindrical geometry
- Multi-scale Godunov-type method for cell-centered discrete Lagrangian hydrodynamics
- Hourglass control in linear and nonlinear problems
- The discrete energy-momentum method. Conserving algorithms for nonlinear elastodynamics
- A second-order Godunov algorithm for two-dimensional solid mechanics
- Design of simple low order finite elements for large strain analysis of nearly incompressible solids
- Dynamic solid mechanics using finite volume methods
- A stabilised Petrov-Galerkin formulation for linear tetrahedral elements in compressible, nearly incompressible and truly incompressible fast dynamics
- A first order hyperbolic framework for large strain computational solid dynamics. I: Total Lagrangian isothermal elasticity
- A computational framework for polyconvex large strain elasticity
- An upwind cell centred total Lagrangian finite volume algorithm for nearly incompressible explicit fast solid dynamic applications
- A total Lagrangian upwind smooth particle hydrodynamics algorithm for large strain explicit solid dynamics
- A cell-centered Lagrangian Godunov-like method for solid dynamics
- A nominally second-order cell-centered Lagrangian scheme for simulating elastic-plastic flows on two-dimensional unstructured grids
- A new Jameson-Schmidt-Turkel smooth particle hydrodynamics algorithm for large strain explicit fast dynamics
- Implicit finite incompressible elastodynamics with linear finite elements: a stabilized method in rate form
- A variationally consistent streamline upwind Petrov-Galerkin smooth particle hydrodynamics algorithm for large strain solid dynamics
- A velocity/stress mixed stabilized nodal finite element for elastodynamics: analysis and computations with strongly and weakly enforced boundary conditions
- An upwind vertex centred finite volume solver for Lagrangian solid dynamics
- A finite volume method for incompressible linear elasticity
- A first order hyperbolic framework for large strain computational solid dynamics. II: Total Lagrangian compressible, nearly incompressible and truly incompressible elasticity
- A numerical method for solving incompressible viscous flow problems
- Lagrangian gas dynamics in two dimensions and Lagrangian systems
- Stability and comparison of different linear tetrahedral formulations for nearly incompressible explicit dynamic applications
- An averaged nodal deformation gradient linear tetrahedral element for large strain explicit dynamic applications
- A locking-free selective smoothed finite element method using tetrahedral and triangular elements with adaptive mesh rezoning for large deformation problems
- A simple, stable, and accurate linear tetrahedral finite element for transient, nearly, and fully incompressible solid dynamics: a dynamic variational multiscale approach
- A higher-order Godunov method for modeling finite deformation in elastic-plastic solids
- A stabilized nodally integrated tetrahedral
- A Cell-Centered Lagrangian Scheme for Two-Dimensional Compressible Flow Problems
- A uniform nodal strain tetrahedron with isochoric stabilization
- A variationally consistent mesh adaptation method for triangular elements in explicit Lagrangian dynamics
- Generalization of selective integration procedures to anisotropic and nonlinear media
- An alpha modification of Newmark's method
- One-Sided Difference Approximations for Nonlinear Conservation Laws
- A uniform strain hexahedron and quadrilateral with orthogonal hourglass control
- A vertex-based finite volume method applied to non-linear material problems in computational solid mechanics
- Application of the finite volume method and unstructured meshes to linear elasticity
- Node-based uniform strain elements for three-node triangular and four-node tetrahedral meshes
- Constraint-Preserving Upwind Methods for Multidimensional Advection Equations
- An assessment of the average nodal volume formulation for the analysis of nearly incompressible solids under finite strains
- A finite volume cell‐centered Lagrangian hydrodynamics approach for solids in general unstructured grids
- A Lagrangian cell‐centred finite volume method for metal forming simulation
- Nonlinear Continuum Mechanics for Finite Element Analysis
