Numerical homogenization ofN-component composites including stochastic interface defects
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Publication:4943441
DOI<1001::AID-NME814>3.0.CO;2-V 10.1002/(SICI)1097-0207(20000220)47:5<1001::AID-NME814>3.0.CO;2-VzbMath0985.74054OpenAlexW2168502953MaRDI QIDQ4943441
Marcin Kaminski, Michal Kleiber
Publication date: 18 May 2002
Full work available at URL: https://doi.org/10.1002/(sici)1097-0207(20000220)47:5<1001::aid-nme814>3.0.co;2-v
homogenizationMonte Carlo simulationeffective modulus methodMCCEFF systemprobabilistic averaging methodrandom periodic fiber \(N\)-component constituentstochastic interface defects
Composite and mixture properties (74E30) Random materials and composite materials (74A40) Homogenization in equilibrium problems of solid mechanics (74Q05)
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Cites Work
- Unnamed Item
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- Multiple scale analysis of heterogeneous elastic structures using homogenization theory and Voronoi cell finite element method
- Estimation of effective elastic moduli for composites
- Derivation of the in-plane elastic characteristics of masonry through homogenization theory
- Linear elasticity of planar Delaunay networks: Random field characterization of effective moduli
- Variational bounds on the effective moduli of anisotropic composites
- A variational approach to the theory of the elastic behaviour of multiphase materials
- Non-homogeneous media and vibration theory
- Homogenized constitutive law for a partially cohesive composite material
- Limit distributions of the states and homogenization in random media
- A numerical model for thermomechanical contact based on microscopic interface laws
- Materials with prescribed constitutive parameters: An inverse homogenization problem
- 3-D finite element analysis of composite beams with parallel fibres, based on homogenization theory
- The application of interface elements and enriched or rate-dependent continua to micro-mechanical analyses of fracture in composites
- Optimal design of piezoelectric microstructures
- Digital image-based modeling applied to the homogenization analysis of composite materials
- Complex moduli of viscoelastic composites. I: General theory and application to particulate composites
- Homogenization of elliptic equations with principal part not in divergence form and hamiltonian with quadratic growth
- Optimal design and relaxation of variational problems, I
- Optimal Bounds and Microgeometries for Elastic Two-Phase Composites
- Real contact mechanisms and finite element formulation—a coupled thermomechanical approach
- Stress-based finite element analysis of plane plasticity problems
- Application of augmented Lagrangian techniques for non‐linear constitutive laws in contact interfaces
- Voronoi cell finite elements
- A parallel Monte‐Carlo finite‐element procedure for the analysis of multicomponent random media
