Extension of the enhanced assumed strain method based on the structure of polyconvex strain-energy functions
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Publication:6497746
DOI10.1002/NME.6284WikidataQ126589043 ScholiaQ126589043MaRDI QIDQ6497746
Peter Betsch, Robin Pfefferkorn
Publication date: 6 May 2024
Published in: International Journal for Numerical Methods in Engineering (Search for Journal in Brave)
eigenvalue analysismixed finite elementsfinite deformationshourglassingenhanced assumed strainpolyconvex strain-energy functions
Numerical and other methods in solid mechanics (74Sxx) Plastic materials, materials of stress-rate and internal-variable type (74Cxx) Elastic materials (74Bxx)
Cites Work
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- A new mixed finite element based on different approximations of the minors of deformation tensors
- Variational and projection methods for the volume constraint in finite deformation elasto-plasticity
- An improved EAS brick element for finite deformation
- A framework for finite strain elastoplasticity based on maximum plastic dissipation and the multiplicative decomposition. I: Continuum formulation
- A framework for finite strain elastoplasticity based on maximum plastic dissipation and the multiplicative decomposition. II: Computational aspects
- Algorithms for static and dynamic multiplicative plasticity that preserve the classical return mapping schemes of the infinitesimal theory
- A class of equivalent enhanced assumed strain and hybrid stress finite elements
- An efficient 3D enhanced strain element with Taylor expansion of the shape functions
- A note on enhanced strain methods for large deformations
- On the stability of mixed finite elements in large strain analysis of incompressible solids
- A deformation-dependent stabilization technique, exemplified by EAS elements at large strains
- A computational framework for polyconvex large strain elasticity
- Enhanced lower-order element formulations for large strains
- Improved versions of assumed enhanced strain tri-linear elements for 3D finite deformation problems
- A mixed variational framework for the design of energy-momentum schemes inspired by the structure of polyconvex stored energy functions
- An energy-momentum time integration scheme based on a convex multi-variable framework for non-linear electro-elastodynamics
- A mixed variational framework for the design of energy-momentum integration schemes based on convex multi-variable electro-elastodynamics
- Towards an efficient computational strategy for electro-activation in cardiac mechanics
- Compatible-strain mixed finite element methods for 3D compressible and incompressible nonlinear elasticity
- Compatible-strain mixed finite element methods for 2D compressible nonlinear elasticity
- A framework for polyconvex large strain phase-field methods to fracture
- On a physically stabilized one point finite element formulation for three-dimensional finite elasto-plasticity
- A robust nonlinear solid shell element based on a mixed variational formulation
- On the formulation of enhanced strain finite elements in finite deformations
- Stabilization of mixed tetrahedral elements at large deformations
- A theorem regarding the locking of tapered four-noded membrane elements
- The patch test—a condition for assessing FEM convergence
- On the limits of finite element perfectability
- Geometrically non-linear enhanced strain mixed methods and the method of incompatible modes
- A non-conforming element for stress analysis
- Computation of isotropic tensor functions
- A geometrical non-linear brick element based on the EAS-method
- Analysis of 3D problems using a new enhanced strain hexahedral element
- A stabilization technique to avoid hourglassing in finite elasticity
- A highly efficient enhanced assumed strain physically stabilized hexahedral element
- A quadrilateral mixed finite element with two enhanced strain modes
- Remarks on the stability of enhanced strain elements in finite elasticity and elastoplasticity
- Stability and Convergence of a Class of Enhanced Strain Methods
- A class of mixed assumed strain methods and the method of incompatible modes
- EAS‐elements for two‐dimensional, three‐dimensional, plate and shell structures and their equivalence to HR‐elements
- Nonlinear Continuum Mechanics for Finite Element Analysis
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