Modified mixed least-squares finite element formulations for small and finite strain plasticity
From MaRDI portal
Publication:6555265
DOI10.1002/nme.5951zbMATH Open1548.74111MaRDI QIDQ6555265
Karl Steeger, Alexander Schwarz, J. Schröder, Maximilian Igelbüscher
Publication date: 14 June 2024
Published in: International Journal for Numerical Methods in Engineering (Search for Journal in Brave)
Small-strain, rate-independent theories of plasticity (including rigid-plastic and elasto-plastic materials) (74C05) Finite element methods applied to problems in solid mechanics (74S05) Finite element, Rayleigh-Ritz and Galerkin methods for boundary value problems involving PDEs (65N30)
Cites Work
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Title not available (Why is that?)
- Weighted overconstrained least-squares mixed finite elements for static and dynamic problems in quasi-incompressible elasticity
- Allgemeine Kontinuumstheorie der Versetzungen und Eigenspannungen
- Finite deformation constitutive equations and a time integration procedure for isotropic, hyperelastic-viscoplastic solids
- Least-squares finite element methods
- 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
- On a stress resultant geometrically exact shell model. Part V: Nonlinear plasticity: Formulation and integration algorithms
- Algorithms for static and dynamic multiplicative plasticity that preserve the classical return mapping schemes of the infinitesimal theory
- Computational inelasticity
- Plasticity. Mathematical theory and numerical analysis
- A physically nonlinear dual mixed finite element formulation
- Automatic generation of finite-element code by simultaneous optimization of expressions
- Mechanik der festen Körper im plastisch-deformablen Zustand.
- First-order system least squares for velocity-vorticity-pressure form of the Stokes equations, with application to linear elasticity
- Mass- and momentum conservation of the least-squares spectral element method for the Stokes problem
- The finite element method with Lagrangian multipliers
- First-order system least squares (FOSLS) for spatial linear elasticity: Pure traction
- On the formulation of enhanced strain finite elements in finite deformations
- A First-Order System Least Squares Method for Hyperelasticity
- Least-Squares Mixed Finite Element Formulations for Isotropic and Anisotropic Elasticity at Small and Large Strains
- Automation of Finite Element Methods
- Adaptive Least Squares Finite Element Methods in Elasto-Plasticity
- Analysis of a Modified First-Order System Least Squares Method for Linear Elasticity with Improved Momentum Balance
- An adaptive least squares mixed finite element method for the stress-displacement formulation of linear elasticity
- A hyperelastic-based large strain elasto-plastic constitutive formulation with combined isotropic-kinematic hardening using the logarithmic stress and strain measures
- The least-squares meshfree method for elasto-plasticity and its application to metal forming analysis
- A modified least-squares mixed finite element with improved momentum balance
- Least-squares mixed finite elements for small strain elasto-viscoplasticity
- The Thermomechanics of Plasticity and Fracture
- Issues Related to Least-Squares Finite Element Methods for the Stokes Equations
- First-Order System Least Squares for the Stokes Equations, with Application to Linear Elasticity
- First-Order System Least Squares (FOSLS) for Planar Linear Elasticity: Pure Traction Problem
- First-Order System Least Squares for the Stress-Displacement Formulation: Linear Elasticity
- First-Order System Least Squares For Linear Elasticity: Numerical Results
- First-Order System Least Squares for the Stokes and Linear Elasticity Equations: Further Results
- Least-Squares Methods for Linear Elasticity
- Mixed Finite Element Methods and Applications
- First‐Order System Least Squares for Geometrically Nonlinear Elasticity
- An Adaptive Least‐Squares Mixed Finite Element Method for Elasto‐Plasticity
- Elastic-Plastic Deformation at Finite Strains
- On a Variational Theorem in Elasticity
- Different approaches for mixed LSFEMs in hyperelasticity: application of logarithmic deformation measures
This page was built for publication: Modified mixed least-squares finite element formulations for small and finite strain plasticity
Report a bug (only for logged in users!)Click here to report a bug for this page (MaRDI item Q6555265)
