ProductsAbaqus/StandardAbaqus/Explicit TypeModel data
LevelPartPart instance
Optional parameters
- ALPHA
-
Set this parameter equal to the
factor to create Rayleigh mass proportional damping in the following
procedures:
The default is ALPHA=0. (Units of
T−1.)
In
Abaqus/Standard
set ALPHA=TABULAR to specify that the mass proportional viscous damping is
dependent on temperature.
In
Abaqus/Explicit
set ALPHA=TABULAR to specify that the mass proportional damping is dependent on
temperature and/or field variables.
-
BAND LIMITED
-
This parameter applies only to Abaqus/Explicit analyses.
Set this parameter equal to the damping ratio,
, used in the band-limited damping. The default is
BAND LIMITED=0.
Set
BAND LIMITED=TABULAR
to specify that the damping ratio in band-limited damping is dependent on temperature
and/or field variables.
- BETA
-
Set this parameter equal to the
factor to create Rayleigh stiffness proportional damping in the following
procedures:
The default is BETA=0. (Units of T.)
In
Abaqus/Standard
set BETA=TABULAR to specify that the stiffness proportional viscous damping is
dependent on temperature.
In
Abaqus/Explicit
set BETA=TABULAR to specify that the stiffness proportional damping is
dependent on temperature and/or field dependent variables.
- COMPOSITE
-
This parameter applies only to
Abaqus/Standard
analyses.
Set this parameter equal to the fraction of critical damping to be used with
this material in calculating composite damping factors for the modes. Composite
damping is used in mode-based procedures that follow subspace iteration
eigenvalue extraction or eigenvalue extraction using the Lanczos eigensolver
with SIM=NO,
except for
STEADY STATE DYNAMICS, SUBSPACE PROJECTION. Use the
MODAL DAMPING, VISCOUS=COMPOSITE option to activate composite modal damping.
The default is COMPOSITE=0.
- DEPENDENCIES
-
This parameter applies only to
Abaqus/Explicit
analyses when ALPHA=TABULAR and/or BETA=TABULAR.
Set this parameter equal to the number of field variables included in the
definition of the
and/or
factors, in addition to temperature. If this parameter is omitted, it is
assumed that Rayleigh damping is constant or depends only on temperature.
See
Specifying Field Variable Dependence
for more information.
-
HIGH FREQUENCY CUTOFF
-
This parameter applies only to Abaqus/Explicit analyses and is valid only when the
BAND LIMITED parameter is used.
Set this parameter equal to the frequency value,
, to define the upper limit of the frequency range. (Units of
cycles/time.)
-
LOW FREQUENCY CUTOFF
-
This parameter applies only to Abaqus/Explicit analyses and is valid only when the
BAND LIMITED parameter is used.
Set this parameter equal to the frequency value,
, to define the lower limit of the frequency range. (Units of
cycles/time.)
- STRUCTURAL
-
Set this parameter equal to the
factor to create stiffness proportional structural damping in the following
procedures:
The default is STRUCTURAL=0.
In
Abaqus/Standard
set STRUCTURAL=TABULAR to specify that the stiffness proportional structural damping
is dependent on temperature.
Data lines to
define temperature and/or field variable-dependent mass proportional damping (ALPHA=TABULAR) in
Abaqus/Explicit
- First line
-
-
.
(Units of T−1.)
-
Temperature.
-
First field variable.
-
Second field variable.
-
Etc., up to six field variables.
- Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than six)
-
Seventh field variable.
-
Etc., up to eight field variables per line.
Repeat this set of data
lines as often as necessary to define the alpha damping as a function of
temperature and other predefined field
variables.
Data lines to define
temperature-dependent mass proportional viscous damping (ALPHA=TABULAR) in
Abaqus/Standard - First line
-
-
.
(Units of T−1.)
-
Temperature.
Repeat this data line as
often as necessary to define the alpha damping as a function of
temperature.
Data lines to define a temperature and/or field variable-dependent damping
ratio in band-limited damping
(BAND LIMITED=TABULAR)
in Abaqus/Explicit
- First line
-
.
Temperature.
First field variable.
Second field variable.
Etc., up to six field variables.
- Subsequent lines (only needed if the
DEPENDENCIES parameter has a value
greater than six)
-
Seventh field variable.
Etc., up to eight field variables per line.
Repeat this set of data lines as often as necessary to define the
damping ratio as a function of temperature and other predefined field
variables.
Data lines to
define temperature and/or field variable-dependent stiffness proportional
damping (BETA=TABULAR) in
Abaqus/Explicit - First line
-
-
.
(Units of T.)
-
Temperature.
-
First field variable.
-
Second field variable.
-
Etc., up to six field variables.
- Subsequent lines
(only needed if the DEPENDENCIES parameter has a value greater than six)
-
Seventh field variable.
-
Etc., up to eight field variables per line.
Repeat this set of
data lines as often as necessary to define the beta damping as a function of
temperature and other predefined field
variables.
Data lines to define
temperature-dependent stiffness proportional viscous damping (BETA=TABULAR) in
Abaqus/Standard - First line
-
-
.
(Units of T.)
-
Temperature.
Repeat this data line as
often as necessary to define the stiffness proportional viscous damping as a
function of temperature.
Data
lines to define temperature-dependent stiffness proportional structural damping (STRUCTURAL=TABULAR) in
Abaqus/Standard - First line
-
-
.
-
Temperature.
Repeat this data line as often as necessary to define the
structural damping as a function of temperature.
Data lines to
define both temperature and/or field variable-dependent mass and stiffness
proportional damping (both ALPHA=TABULAR and BETA=TABULAR) in
Abaqus/Explicit
- First line
-
-
.
(Units of T−1.)
-
.
(Units of T.)
-
Temperature.
-
First field variable.
-
Second field variable.
-
Etc., up to five field variables.
- Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five)
-
Sixth field variable.
-
Etc., up to eight field variables per line.
Repeat this set
of data lines as often as necessary to define the alpha and beta damping as a
function of temperature and other predefined field
variables.
Data lines to define both temperature and/or field variable-dependent mass
proportional damping and band-limited damping (both
ALPHA=TABULAR
and
BAND LIMITED=TABULAR)
in Abaqus/Explicit
- First line
-
. (Units of T−1.)
.
Temperature.
First field variable.
Second field variable.
Etc., up to five field variables.
- Subsequent lines (only needed if the
DEPENDENCIES parameter has a value
greater than five)
-
Sixth field variable.
Etc., up to eight field variables per line.
Repeat this set of data lines as often as necessary to define the
mass proportional and band-limited damping as a function of temperature and other
predefined field variables.
Data lines to define both temperature and/or field variable-dependent stiffness
proportional damping and band-limited damping (both
BETA=TABULAR
and
BAND LIMITED=TABULAR)
in Abaqus/Explicit
- First line
-
. (Units of T.)
.
Temperature.
First field variable.
Second field variable.
Etc., up to five field variables.
- Subsequent lines (only needed if the
DEPENDENCIES parameter has a value
greater than five)
-
Sixth field variable.
Etc., up to eight field variables per line.
Repeat this set of data lines as often as necessary to define the
stiffness proportional and band-limited damping as a function of temperature and other
predefined field variables.
Data lines to define temperature and/or field variable-dependent mass
proportional, stiffness proportional, and band-limited damping
(ALPHA=TABULAR,
BETA=TABULAR,
and
BAND LIMITED=TABULAR)
in Abaqus/Explicit
- First line
-
. (Units of T−1.)
. (Units of T.)
.
Temperature.
First field variable.
Second field variable.
Etc., up to four field variables.
- Subsequent lines (only needed if the
DEPENDENCIES parameter has a value
greater than four)
-
Fifth field variable.
Etc., up to eight field variables per line.
Repeat this set of data lines as often as necessary to define the
mass proportional, stiffness proportional, and band-limited damping as a function of
temperature and other predefined field variables.
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