Accurate solutions
Abaqus Standard, a robust implicit solver to perform highly accurate static and low-speed dynamic events.
Utilize co-simulation
Perform multiple co-simulations through in the same analysis and combine different behaviours.
Switch between solvers
Simply switch your solver type and go from implicit to explicit or vice versa with the same interface.
Many analysis types
Perform many analysis types to analyse if your product withstands many real-life behaviours.
Abaqus Standard
The implicit non-linear solver for static and structural low-speed dynamic events
Many analysis types
Robust solutions techniques
Define material specifications
Functionalities SIMULIA Abaqus Standard
Accurate implicit solver to reach realistic results
Many analysis types
Abaqus Standard can perform Linear and non-linear static and structural low-speed dynamic events
Many analysis types
• Static stress/displacement analysis
• Viscoelastic/viscoplastic response
• Dynamic stress/displacement analysis
• Heat transfer analysis (transient and steady-state)
• Mass diffusion analysis (transient and steady-state)
• Direct cyclic > Low-cycle fatigue
• Acoustic analysis
• Coupled problems > Thermo-mechanical > Thermo-electrical > Piezoelectric > Coupled thermal-electricalstructural > Pore fluid flow-mechanical > Thermo-mechanical mass diffusion > Shock and acoustic structural
• Cosimulation > Abaqus/Standard to Abaqus/Explicit > Abaqus/CFD to Abaqus/Standard or Abaqus/Explicit > Fluid structure interaction (FSI) > Conjugate heat transfer
• Flow analysis > Laminar and turbulent
Linear Perturbation Analyses
• Static stress/displacement analysis > Linear static stress/displacement analysis > Eigenvalue buckling estimates
• Dynamic stress/displacement analysis > Natural frequency extraction > Complex eigenvalue extraction > Transient response via modal superposition > Steady-state response to harmonic loading > Response spectrum analysis > Random response analysis
• Substructure Generation
• Electromagnetic, time harmonic
Robust solution techniques
Use different solutions techniques to reach convergence an accuracy
Robust solution techniques
• Parallel direct sparse solver with dynamic load balancing
• Parallel iterative solver
• Parallel Lanczos eigenvalue solution
• Parallel AMS eigenvalue solution
• Parallel element operations
• Multiple load cases
• Full Newton and quasi- Newton methods
• GPGPU accelerated sparse solver
Define material specifications
Apply many types of mechanical material models
Define material specifications
• Linear elasticity
• Orthotropic and anisotropic linear elasticity
• Porous elasticity
• Hypoelasticity
• Hyperelasticity (including permanent set)
• Anisotropic hyperelasticity
• Elastomeric foam
• Mullins effect
• Viscoelasticity
• Nonlinear viscoelasticity
• Hysteresis
Inelastic Mechanical Properties
• Metal plasticity > Isotropic and anisotropic yield criteria > Isotropic, kinematic, and ORNL hardening > Porous metal plasticity > Cast iron > Two-layer viscoplasticity > Creep > Volumetric swelling > Deformation plasticity > Johnson-Cook plasticity
• Extended Drucker-Prager plasticity
• Capped Drucker-Prager plasticity
• Cam-Clay plasticity
• Mohr-Coulomb plasticity
• Crushable foam plasticity
• Jointed materials
• Concrete
• Progressive damage and failure > Ductile > Shear > Forming limit diagram (FLD) > Forming limit stress diagram (FLSD) > Müschenborn-Sonne forming limit diagram (MSFLD) > Hashin unidirectional composite