A combined \(r-h\) adaptive strategy based on material forces and error assessment for plane problems and bimaterial interfaces
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Publication:1021046
DOI10.1007/s00466-007-0168-8zbMath1162.74475OpenAlexW1969141317MaRDI QIDQ1021046
Publication date: 8 June 2009
Published in: Computational Mechanics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00466-007-0168-8
Finite element methods applied to problems in solid mechanics (74S05) Generalities, axiomatics, foundations of continuum mechanics of solids (74A99)
Related Items (8)
WAMR: an adaptive wavelet method for the simulation of compressible reacting flow. Part I: Accuracy and efficiency of algorithm ⋮ An integrated approach to shape optimization and mesh adaptivity based on material residual forces ⋮ Fast \(r\)-adaptivity for multiple queries of heterogeneous stochastic material fields ⋮ An adaptive wavelet method for nonlinear partial differential equations with applications to dynamic damage modeling ⋮ Goal-oriented \(r\)-adaptivity based on variational arguments in the physical and material spaces ⋮ r-Adaptation algorithm guided by gradients of strain energy density ⋮ An Adaptive Wavelet Collocation Method for Solution of the Convection-Dominated Problem on a Sphere ⋮ Energy Based Adaptive Strategy for Plates and Laminates
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- On material forces and finite element discretizations
- Material forces in open system mechanics
- Accuracy and optimal meshes in finite element computation for nearly incompressible materials
- Adaptive remeshing for three-dimensional compressible flow computations
- The elastic energy-momentum tensor
- A note on the optimal choice of finite element grids
- Adaptive grid optimization for structural analysis -- Geometry-based approach
- On configurational inertial forces at a phase interface
- Configurational forces: Are they needed?
- Configurational forces -- morphology evolution and finite elements.
- r-refinement grid adaptation algorithms and issues
- Application of material forces to hyperelastostatic fracture mechanics. I: Continuum mechanical setting
- Use of material forces in adaptive finite element methods
- An automatic procedure with a control of accuracy for finite element analysis in 2D elasticity
- An ALE formulation based on spatial and material settings of continuum mechanics. II: Classification and applications
- A combined rh‐adaptive scheme based on domain subdivision. Formulation and linear examples
- A Performance Study on Configurational Force and Spring-Analogy Based Mesh Optimization Schemes
- Analysis of the Zienkiewicz-Zhua-posteriori error estimator in the finite element method
- Adaptive FEM computation of forming processes—Application to porous and non-porous materials
- A simple error estimator and adaptive procedure for practical engineerng analysis
- An algorithm for defining a single near-optimum mesh for multiple-load-case problems
- Adaptivity and mesh generation
- The superconvergent patch recovery anda posteriori error estimates. Part 1: The recovery technique
- An energy basis for mesh refinement of structural continua
- Effective stress-based finite element error estimation for composite bodies
- On configurational forces in the context of the finite element method
- CRITERIA TO ACHIEVE NEARLY OPTIMAL MESHES IN THEh-ADAPTIVE FINITE ELEMENT METHOD
- Mechanics in Material Space
- Local and global smoothing of discontinuous finite element functions using a least squares method
- "Material" mechanics of materials
- Theoretical formulations for adaptive finite element computations
- A variational r‐adaption and shape‐optimization method for finite‐deformation elasticity
- Structural optimization by simultaneous equilibration of spatial and material forces
- Application of material forces to hyperelastostatic fracture mechanics. II: Computational setting.
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