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OI.1 Abaqus/Standard Output Variable Index
OI.2 Abaqus/Explicit Output Variable Index
OI.3 Abaqus/CFD Output Variable Index
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# Volume II
# PART III ANALYSIS PROCEDURES, SOLUTION, AND CONTROL
# 6. Analysis Procedures
# Introduction
Solving analysis problems: overview 6.1.1
Defining an analysis 6.1.2
General and linear perturbation procedures 6.1.3
Multiple load case analysis 6.1.4
Direct linear equation solver 6.1.5
Iterative linear equation solver 6.1.6
# Static stress/displacement analysis
Static stress analysis procedures: overview 6.2.1
Static stress analysis 6.2.2
Eigenvalue buckling prediction 6.2.3
Unstable collapse and postbuckling analysis 6.2.4
Quasi-static analysis 6.2.5
Direct cyclic analysis 6.2.6
Low-cycle fatigue analysis using the direct cyclic approach 6.2.7
# Dynamic stress/displacement analysis
Dynamic analysis procedures: overview 6.3.1
Implicit dynamic analysis using direct integration 6.3.2
Explicit dynamic analysis 6.3.3
Direct-solution steady-state dynamic analysis 6.3.4
Natural frequency extraction 6.3.5
Complex eigenvalue extraction 6.3.6
Transient modal dynamic analysis 6.3.7
Mode-based steady-state dynamic analysis 6.3.8
Subspace-based steady-state dynamic analysis 6.3.9
Response spectrum analysis 6.3.10
Random response analysis 6.3.11
# Steady-state transport analysis
Steady-state transport analysis 6.4.1
# Heat transfer and thermal-stress analysis
Heat transfer analysis procedures: overview 6.5.1
Uncoupled heat transfer analysis 6.5.2
Fully coupled thermal-stress analysis 6.5.3
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Adiabatic analysis 6.5.4
# Fluid dynamic analysis
Fluid dynamic analysis procedures: overview 6.6.1
Incompressible fluid dynamic analysis 6.6.2
# Electromagnetic analysis
Electromagnetic analysis procedures 6.7.1
Piezoelectric analysis 6.7.2
Coupled thermal-electrical analysis 6.7.3
Fully coupled thermal-electrical-structural analysis 6.7.4
Eddy current analysis 6.7.5
Magnetostatic analysis 6.7.6
# Coupled pore fluid flow and stress analysis
Coupled pore fluid diffusion and stress analysis 6.8.1
Geostatic stress state 6.8.2
# Mass diffusion analysis
Mass diffusion analysis 6.9.1
# Acoustic and shock analysis
Acoustic, shock, and coupled acoustic-structural analysis 6.10.1
# Abaqus/Aqua analysis
Abaqus/Aqua analysis 6.11.1
# Annealing
Annealing procedure 6.12.1
# 7. Analysis Solution and Control
# Solving nonlinear problems
Solving nonlinear problems 7.1.1
# Analysis convergence controls
Convergence and time integration criteria: overview 7.2.1
Commonly used control parameters 7.2.2
Convergence criteria for nonlinear problems 7.2.3
Time integration accuracy in transient problems 7.2.4
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# PART IV ANALYSIS TECHNIQUES
# 8. Analysis Techniques: Introduction
# Introduction
Analysis techniques: overview 8.1.1
# 9. Analysis Continuation Techniques
# Restarting an analysis
Restarting an analysis 9.1.1
# Importing and transferring results
Transferring results between Abaqus analyses: overview 9.2.1
Transferring results between Abaqus/Explicit and Abaqus/Standard 9.2.2
Transferring results from one Abaqus/Standard analysis to another 9.2.3
Transferring results from one Abaqus/Explicit analysis to another 9.2.4
# 10. Modeling Abstractions
# Substructuring
Using substructures 10.1.1
Defining substructures 10.1.2
# Submodeling
Submodeling: overview 10.2.1
Node-based submodeling 10.2.2
Surface-based submodeling 10.2.3
# Generating matrices
Generating matrices 10.3.1
Generating thermal matrices 10.3.2
# Symmetric model generation, results transfer, and analysis of cyclic symmetry models
Symmetric model generation 10.4.1
Transferring results from a symmetric mesh or a partial three-dimensional mesh to a full three-dimensional mesh 10.4.2
Analysis of models that exhibit cyclic symmetry 10.4.3
# Periodic media analysis
Periodic media analysis 10.5.1
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# Meshed beam cross-sections
Meshed beam cross-sections 10.6.1
# Modeling discontinuities as an enriched feature using the extended finite element method
Modeling discontinuities as an enriched feature using the extended finite element method 10.7.1
# 11. Special-Purpose Techniques
# Inertia relief
Inertia relief 11.1.1
# Mesh modification or replacement
Element and contact pair removal and reactivation 11.2.1
# Geometric imperfections
Introducing a geometric imperfection into a model 11.3.1
# Fracture mechanics
Fracture mechanics: overview 11.4.1
Contour integral evaluation 11.4.2
Crack propagation analysis 11.4.3
# Surface-based fluid modeling
Surface-based fluid cavities: overview 11.5.1
Fluid cavity definition 11.5.2
Fluid exchange definition 11.5.3
Inflator definition 11.5.4
# Mass scaling
Mass scaling 11.6.1
# Selective subcycling
Selective subcycling 11.7.1
# Steady-state detection
Steady-state detection 11.8.1
# 12. Adaptivity Techniques
# Adaptivity techniques: overview
Adaptivity techniques 12.1.1
# ALE adaptive meshing
ALE adaptive meshing: overview 12.2.1
Defining ALE adaptive mesh domains in Abaqus/Explicit 12.2.2
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ALE adaptive meshing and remapping in Abaqus/Explicit 12.2.3
Modeling techniques for Eulerian adaptive mesh domains in Abaqus/Explicit 12.2.4
Output and diagnostics for ALE adaptive meshing in Abaqus/Explicit 12.2.5
Defining ALE adaptive mesh domains in Abaqus/Standard 12.2.6
ALE adaptive meshing and remapping in Abaqus/Standard 12.2.7
# Adaptive remeshing
Adaptive remeshing: overview 12.3.1
Selection of error indicators influencing adaptive remeshing 12.3.2
Solution-based mesh sizing 12.3.3
# Analysis continuation after mesh replacement
Mesh-to-mesh solution mapping 12.4.1
# 13. Optimization Techniques
# Structural optimization: overview
Structural optimization: overview 13.1.1
# Optimization models
Design responses 13.2.1
Objectives and constraints 13.2.2
Creating Abaqus optimization models 13.2.3
# 14. Eulerian Analysis
# Eulerian analysis
Eulerian analysis 14.1.1
Defining Eulerian boundaries 14.1.2
Eulerian mesh motion 14.1.3
Defining adaptive mesh refinement in the Eulerian domain 14.1.4
# 15. Particle Methods
# Discrete element method
Discrete element method 15.1.1
# Continuum particle analyses
Smoothed particle hydrodynamics 15.2.1
Finite element conversion to SPH particles 15.2.2
# Particle generator
Particle generator 15.3.1
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# 16. Sequentially Coupled Multiphysics Analyses
# Sequentially coupled multiphysics analyses
Predefined fields for sequential coupling 16.1.1
Sequentially coupled thermal-stress analysis 16.1.2
Predefined loads for sequential coupling 16.1.3
# 17. Co-simulation
# Co-simulation
Co-simulation: overview 17.1.1
# Preparing an Abaqus analysis for co-simulation
Preparing an Abaqus analysis for co-simulation 17.2.1
# Co-simulation between Abaqus solvers
Structural-to-structural co-simulation 17.3.1
Fluid-to-structural and conjugate heat transfer co-simulation 17.3.2
Electromagnetic-to-structural and electromagnetic-to-thermal co-simulation 17.3.3
Executing a co-simulation 17.3.4
# Co-simulation using Abaqus and discrete models
Structural-to-logical co-simulation 17.4.1
# 18. Extending Abaqus Analysis Functionality
# User subroutines and utilities
User subroutines: overview 18.1.1
Available user subroutines 18.1.2
Available utility routines 18.1.3
# 19. Design Sensitivity Analysis
# Design sensitivity analysis
Design sensitivity analysis 19.1.1
# 20. Parametric Studies
# Scripting parametric studies
Scripting parametric studies 20.1.1
# Parametric studies: commands
aStudy.combine(): Combine parameter samples for parametric studies. 20.2.1
aStudy.constrain(): Constrain parameter value combinations in parametric studies. 20.2.2
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# CONTENTS
aStudy.define(): Define parameters for parametric studies. 20.2.3
aStudy.execute(): Execute the analysis of parametric study designs. 20.2.4
aStudy.gather(): Gather the results of a parametric study. 20.2.5
aStudy.generate(): Generate the analysis job data for a parametric study. 20.2.6
aStudy.output(): Specify the source of parametric study results. 20.2.7
aStudy=ParStudy(): Create a parametric study. 20.2.8
aStudy.report(): Report parametric study results. 20.2.9
aStudy.sample(): Sample parameters for parametric studies. 20.2.10
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# Volume III
# PART V MATERIALS
# 21. Materials: Introduction
# Introduction
Material library: overview 21.1.1
Material data definition 21.1.2
Combining material behaviors 21.1.3
# General properties
Density 21.2.1
# 22. Elastic Mechanical Properties
# Overview
Elastic behavior: overview 22.1.1
# Linear elasticity
Linear elastic behavior 22.2.1
No compression or no tension 22.2.2
Plane stress orthotropic failure measures 22.2.3
# Porous elasticity
Elastic behavior of porous materials 22.3.1
# Hypoelasticity
Hypoelastic behavior 22.4.1
# Hyperelasticity
Hyperelastic behavior of rubberlike materials 22.5.1
Hyperelastic behavior in elastomeric foams 22.5.2
Anisotropic hyperelastic behavior 22.5.3
# Stress softening in elastomers
Mullins effect 22.6.1
Energy dissipation in elastomeric foams 22.6.2
# Linear viscoelasticity
Time domain viscoelasticity 22.7.1
Frequency domain viscoelasticity 22.7.2
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# Nonlinear viscoelasticity
Hysteresis in elastomers 22.8.1
Parallel rheological framework 22.8.2
# Rate sensitive elastomeric foams
Low-density foams 22.9.1
# 23. Inelastic Mechanical Properties
# Overview
Inelastic behavior 23.1.1
# Metal plasticity
Classical metal plasticity 23.2.1
Models for metals subjected to cyclic loading 23.2.2
Rate-dependent yield 23.2.3
Rate-dependent plasticity: creep and swelling 23.2.4
Annealing or melting 23.2.5
Anisotropic yield/creep 23.2.6
Johnson-Cook plasticity 23.2.7
Dynamic failure models 23.2.8
Porous metal plasticity 23.2.9
Cast iron plasticity 23.2.10
Two-layer viscoplasticity 23.2.11
ORNL Oak Ridge National Laboratory constitutive model 23.2.12
Deformation plasticity 23.2.13
# Other plasticity models
Extended Drucker-Prager models 23.3.1
Modified Drucker-Prager/Cap model 23.3.2
Mohr-Coulomb plasticity 23.3.3
Critical state (clay) plasticity model 23.3.4
Crushable foam plasticity models 23.3.5
# Fabric materials
Fabric material behavior 23.4.1
# Jointed materials
Jointed material model 23.5.1
# Concrete
Concrete smeared cracking 23.6.1
Cracking model for concrete 23.6.2
Concrete damaged plasticity 23.6.3