Identifier.dat.fil.odbDescription
FieldHistory
quantity for eigenvalue extraction procedures in the results file or as field output in the output database, request ENER. In steady-state dynamic analysis this is the cyclic mean value.
PENEREnergy dissipated by rate-independent and rate-dependent plasticity, per unit volume. Not available for steady-state dynamic analysis.
CENEREnergy dissipated by creep, swelling, viscoelasticity, and energy associated with viscous regularization for cohesive elements, per unit volume. Not available for steady-state dynamic analysis.
VENEREnergy dissipated by viscous effects (except those from viscoelasticity and static dissipation), per unit volume.
EENERElectrostatic energy density. Not available for steady-state dynamic analysis.
JENERElectrical energy dissipated as a result of the flow of current, per unit volume. Not available for steady-state dynamic analysis.
DMENEREnergy dissipated by damage, per unit volume. Not available for steady-state dynamic analysis.
State, field, and user-defined output variables
SDVSolution-dependent state variables.
SDVnSolution-dependent state variable n.
TEMPTemperature.
FVPredefined field variables, including those imported using the FVi co-simulation field ID.
FVnPredefined field variable n.
MFRPredefined mass flow rates.
MFRnComponent n of predefined mass flow rate (n = 1, 2, 3).
UVARMUser-defined output variables.
UVARMnUser-defined output variable n.
Composite failure measures
CFAILUREAll failure measure components.
Identifier.dat.fil.odbDescription
FieldHistory
MSTRSMaximum stress theory failure measure.
TSAIHTsai-Hill theory failure measure.
TSAIWTsai-Wu theory failure measure.
AZZITAzzi-Tsai-Hill theory failure measure.
MSTRNMaximum strain theory failure measure.
Fluid link quantities
MFLCurrent value of the mass flow rate.
MFLTCurrent value of the total mass flow.
Fluid pipe element quantities
FPMFLCurrent value of the mass flow rate.
FPFLVELCurrent velocity of the fluid flowing through the pipe.
FPDPRESSCurrent pressure drop across the element.
Fracture mechanics quantities
JKJ-integral, stress intensity factors. Available only for
Concrete cracking and additional plasticity
CRACK
CONF
PEQC
PEQCn
Unit normal to cracks in concrete. Number of cracks at a concrete material point. All equivalent plastic strains when the model has more than one yield/failure surface. nth equivalent plastic strain $( n = 1 , 2 , 3 , 4 )$ . For jointed materials: PEQC provides equivalent plastic strains for all four possible systems (three joints - PEQC1, PEQC2, PEQC3, and bulk material - PEQC4). This identifier also provides a yes/no flag (1/0 on the output database) telling if each individual system is currently yielding or not (AC YIELD: “actively yielding”; that is, the plastic strain changed during the increment). # Identifier .dat .fil .odb Description Field History For cap plasticity: PEQC provides equivalent plastic strains for all three possible yield/failure surfaces (Drucker-Prager failure surface - PEQC1, cap surface - PEQC2, and transition surface - PEQC3) and the total volumetric inelastic strain (PEQC4). All identifiers also provide a yes/no flag (1/0 on the output database) telling whether the yield surface is currently active or not (AC YIELD: “actively yielding”, that is, the plastic strain changed during the increment). When PEQC is requested as output to the output database, the active yield flags for each component are named AC YIELD1, AC YIELD2, etc. and take the value 1 or 0. Concrete damaged plasticity
DAMAGEC
DAMAGET
SDEG
PEEQ
Compressive damage variable, $d _ { c }$ . Tensile damage variable, $d _ { t }$ Scalar stiffness degradation variable, d. Equivalent plastic strain in uniaxial compression, which is defined as $\int \dot { \bar { \varepsilon } } _ { c } ^ { p l } d t .$ This identifier also provides a yes/no flag (1/0 on the output database) telling if the material is currently undergoing compressive failure or not (AC YIELD: “actively yielding”; that is, the plastic strain changed during the increment). Rebar quantities
RBFOR
RBANG
RBROT
Force in rebar. Angle in degrees between rebar and the user-specified isoparametric direction. Available only for shell, membrane, and surface elements. Change in angle in degrees between rebar and the userspecified isoparametric direction. Available only for shell, membrane, and surface elements.
Identifier.dat.fil.odbDescription
Field History
Heat transfer analysis
HFLCurrent magnitude and components of the heat flux per unit area vector. The integration points for these values are located at the Gauss points.
HFLMCurrent magnitude of heat flux per unit area vector.
HFLnComponent n of the heat flux vector (n = 1, 2, 3).
Mass diffusion analysis
CONCMass concentration.
ISOLAmount of solute at an integration point, calculated as the product of the mass concentration (CONC) and the integration point volume (IVOL).
MFLCurrent magnitude and components of the concentration flux vector.
MFLMCurrent magnitude of the concentration flux vector.
MFLnComponent n of the concentration flux vector (n = 1, 2, 3).
Elements with electrical potential degrees of freedom
EPGCurrent magnitude and components of the electrical potential gradient vector for a coupled thermal-electrical analysis or a fully coupled thermal-electrical-structural analysis. Current magnitude and components of the negative of the electrical potential gradient vector for a piezoelectric analysis.
EPGMCurrent magnitude of the electrical potential gradient vector.
EPGnComponent n of the electrical potential gradient vector for a coupled thermal-electrical analysis or a fully coupled thermal-electrical-structural analysis. Component n of the negative of the electrical potential gradient vector for a piezoelectric analysis. (n = 1, 2, 3) .
Piezoelectric analysis
EFLXCurrent magnitude and components of the electrical flux vector.
Identifier.dat.fil.odbDescription
Field History
EFLXMCurrent magnitude of the electrical flux vector.
EFLXnComponent n of the electrical flux vector (n = 1, 2, 3).
Coupled thermal-electrical elements
ECDCurrent magnitude and components of the electrical current density.
ECDMCurrent magnitude of the electrical current density.
ECDnComponent n of the electrical current density vector
Cohesive elements
MAXSCRTMaximum nominal stress damage initiation criterion.
MAXECRTMaximum nominal strain damage initiation criterion.
QUADSCRTQuadratic nominal stress damage initiation criterion.
QUADECRTQuadratic nominal strain damage initiation criterion.
DMICRTAll active components of the damage initiation criteria.
SDEGOverall scalar stiffness degradation.
STATUSStatus of the element (the status of an element is 1.0 if the element is active, 0.0 if the element is not).
MMIXDMEMode mix ratio during damage evolution. It has a value of -1.0 before initiation of damage.
MMIXDMIMode mix ratio at damage initiation. It has a value of
Low-cycle fatigue analysis
CYCLEININumber of cycles to initialize the damage at the material point.
SDEGOverall scalar stiffness degradation.
STATUSStatus of the element (the status of an element is 1.0 if
Pore pressure analysis
VOIDRVoid ratio.
PORPore pressure.
SATSaturation.
GELVRGel volume ratio.
Identifier.dat.fil.odbDescription
FieldHistory
FLUVRTotal fluid volume ratio.
FLVELCurrent magnitude and components of the pore fluid effective velocity vector.
FLVELMCurrent magnitude of the pore fluid effective velocity vector.
FLVELnComponent n of the pore fluid effective velocity vector (n = 1, 2, 3).
Pore pressure cohesive elements
GFVR
PFOPEN
LEAKVRT
LEAKVRB
ALEAKVRT
ALEAKVRB
Gap flow volume rate. Pore pressure fracture opening. Leak-off flow rate at the top of the element. Leak-off flow rate at the bottom of the element. Accumulated leak-off volume at the top of the element. Accumulated leak-off volume at the bottom of the element. Porous metal plasticity quantities
RD
VVF
VVFG
VVFN
Relative density. Void volume fraction. Void volume fraction due to void growth. Void volume fraction due to void nucleation. Two-layer viscoplasticity quantities
VS $\bullet$ $\bullet$ $\bullet$ $\bullet$
VSij $\bullet$ $\bullet$
PS $\bullet$ $\bullet$ $\bullet$ $\bullet$
PSij $\bullet$ $\bullet$
VE $\bullet$ $\bullet$ $\bullet$ $\bullet$
VEij $\bullet$ $\bullet$
PE $\bullet$ $\bullet$ $\bullet$ $\bullet$
PEij $\bullet$ $\bullet$
Stress in the elastic-viscous network. -component of stress in the elastic-viscous network $( i \leq j \leq 3 )$ . Stress in the elastic-plastic network. -component of stress in the elastic-plastic network $( i \leq j \leq 3 )$ . Viscous strain in the elastic-viscous network. -component of viscous strain in the elastic-viscous network $( i \leq j \leq 3 )$ . Plastic strain in the elastic-plastic network. -component of plastic strain in the elastic-plastic network $( i \leq j \leq 3 )$ .
Identifier.dat.fil.odbDescription
FieldHistory
VEEQEquivalent viscous strain in the elastic-viscous network, defined as $\int_{0}^{t} \dot{\varepsilon}^{v} dt$ .
PEEQEquivalent plastic strain in the elastic-plastic network, defined as $\int_{0}^{t} \dot{\varepsilon}^{pl} dt$ .
Geometric quantities
COORDCoordinates of the integration point for solid elements and rebar. These are the current coordinates if the large-displacement formulation is being used.
IVOLIntegration point volume. Section point volume in the case of beams and shells. (Not available for eigenfrequency extraction, eigenvalue buckling prediction, complex eigenfrequency extraction, or linear dynamics procedures. Available only for continuum and structural elements not using general beam or shell section definitions.)
LOCALDIRnDirection cosines of the local material directions for an anisotropic hyperelastic material model. This variable is output automatically if any other element field output is requested for an anisotropic hyperelastic material (see “Output” in “Anisotropic hyperelastic behavior,” Section 22.5.3).
Accuracy indicators
SJPStrain jumps at nodes.
# Random response analysis The following variables (beginning with R) are available only for random response dynamic analysis:
RSRoot mean square of all stress components.
RSijRoot mean square of ij-component of stress (i ≤ j ≤ 3).
RMISESRoot mean square of Mises equivalent stress.
RERoot mean square of all strain components.
REijRoot mean square of ij-component of strain (i ≤ j ≤ 3).
RCTFRMS values of all components of connector total forces and moments.
Identifier.dat.fil.odbDescription
FieldHistory
RCTFnRMS value of connector total force component n (n = 1, 2, 3).
RCTMnRMS value of connector total moment component n (n = 1, 2, 3).
RCEFRMS values of all components of connector elastic forces and moments.
RCEFnRMS value of connector elastic force component n (n = 1, 2, 3).
RCEMnRMS value of connector elastic moment component n (n = 1, 2, 3).
RCVFRMS values of all components of connector viscous forces and moments.
RCVFnRMS value of connector viscous force component n (n = 1, 2, 3).
RCVMnRMS value of connector viscous moment component n (n = 1, 2, 3).
RCRFRMS values of all components of connector reaction forces and moments.
RCRFnRMS value of connector reaction force component n (n = 1, 2, 3).
RCRMnRMS value of connector reaction moment component n (n = 1, 2, 3).
RCSFRMS values of all components of connector friction forces and moments.
RCSFnRMS value of connector friction force component n (n = 1, 2, 3).
RCSMnRMS value of connector friction moment component n (n = 1, 2, 3).
RCSFCRMS value of connector friction force in the direction of the instantaneous slip direction. Available only if friction is defined in the slip direction.
RCURMS values of all components of connector relative displacements and rotations.
RCUnRMS value of connector relative displacement in the n-direction (n = 1, 2, 3).
RCURnRMS value of connector relative rotation in the n-direction (n = 1, 2, 3).
Identifier.dat.fil.odbDescription
FieldHistory
RCCURMS values of all components of connector constitutive displacements and rotations.
RCCUnRMS value of connector constitutive displacement in the n-direction (n = 1, 2, 3).
RCCURnRMS value of connector constitutive rotation in the n-direction (n = 1, 2, 3).
RCNFRMS values of all components of connector friction-generating contact forces and moments.
RCNFnRMS value of connector friction-generating contact force component n (n = 1, 2, 3).
RCNMnRMS value of connector friction-generating contact moment component n (n = 1, 2, 3).
RCNFCRMS values of connector friction-generating contact force components in the instantaneous slip direction. Available only if friction is defined in the slip direction.
# Steady-state dynamic analysis The following variables (beginning with P) are available only for steady-state (frequency domain) dynamic analysis. These variables include both the magnitude and phase angle for all components. Phase angles are given in degrees. In the data file there are two lines of output for each request. The first line contains the magnitude, and the second line (indicated by the SSD footnote) contains the phase angle. In the results file the magnitudes of all components are first, followed by the phase angles of all components.
PHSMagnitude and phase angle of all stress components.
PHSijMagnitude and phase angle of ij-component of stress (i ≤ j ≤ 3).
PHEMagnitude and phase angle of all strain components.
PHEijMagnitude and phase angle of ij-component of strain (i ≤ j ≤ 3).
PHEPGMagnitude and phase angles of the electrical potential gradient vector.
PHEPGnMagnitude and phase angle of component n of the electrical potential gradient (n = 1, 2, 3).
PHEFLMagnitude and phase angles of the electrical flux vector.
PHEFLnMagnitude and phase angle of component n of the electrical flux vector (n = 1, 2, 3).
Identifier.dat.fil.odbDescription
Field History
PHMFLMagnitude and phase angle of mass flow rate. Available only for fluid link elements.
PHMFTMagnitude and phase angle of total mass flow. Available only for fluid link elements.
PHCTFMagnitude and phase of all components of connector total forces and moments.
PHCTFnMagnitude and phase of connector total force component n (n = 1, 2, 3).
PHCTMnMagnitude and phase of connector total moment component n (n = 1, 2, 3).
PHCEFMagnitude and phase of all components of connector elastic forces and moments.
PHCEFnMagnitude and phase of connector elastic force component n (n = 1, 2, 3).
PHCEMnMagnitude and phase of connector elastic moment component n (n = 1, 2, 3).
PHCVFMagnitude and phase of all components of connector viscous forces and moments.
PHCVFnMagnitude and phase of connector viscous force component n (n = 1, 2, 3).
PHCVMnMagnitude and phase of connector viscous moment component n (n = 1, 2, 3).
PHCRFMagnitude and phase of all components of connector reaction forces and moments.
PHCRFnMagnitude and phase of connector reaction force component n (n = 1, 2, 3).
PHCRMnMagnitude and phase of connector reaction moment component n (n = 1, 2, 3).
PHCSFMagnitude and phase of all components of connector friction forces and moments.
PHCSFnMagnitude and phase of connector friction force component n (n = 1, 2, 3).
PHCSMnMagnitude and phase of connector friction moment component n (n = 1, 2, 3).
PHCSFCMagnitude and phase of connector friction force in the direction of the instantaneous slip direction. Available only if friction is defined in the slip direction.