velocities

Unless otherwise specified, data names are accessible in level 3 only.

engineering_type: The engineering type of load. Engineering loads act on set entities. Valid values are:; 0 - Classic load; 2 - Normal engineering load; 3 - Directional engineering load; Type: unsigned integer

The following data names are available for both classic and engineering loads:

attributesmax

The number of attributes owned by this entity.

Type: unsigned integer

collector

Pointer to the collector that owns the element.

Type: pointer (levels 2, 3 and 4)

config

The configuration of the entity.

8 - Velocity

Type: unsigned integer

definedentity

True if the entity is defined, false otherwise.

Type: Boolean

entityid

The ID of the entity the load is attached to.

Type: integer

entitytype

The type of the entity to which the load is applied.

1 - node
3 - comp
5 - surf
10 - set
27 - point
28 - line

Type: integer

entitytypename

The string type of the entity to which the load is applied.

nodes
comps
surfs
sets
points
lines

id

The ID of the entity.

Type: unsigned integer

include

The ID of the include file the entity is organized in.

Type: entity

includeid

The ID of the include file the entity is organized in.

Type: unsigned integer

internalid

The ID of the entity.

Type: unsigned integer

internalname

The internal name of the entity.

Type: string

moduleid

The module ID of the entity.

Type: integer

poolid

The pool number of the entity.

Type: integer

poolname

The pool name of the entity.

Type: string

set

Pointer to the set when the load is applied to a set.

Type: pointer

solver_id

The solver ID of the entity.

Type: integer

solverkeyword

The name of the solver keyword.

Type: string

solvername

The solver name of the entity for entities enabled for name pool, otherwise the internal name of the entity.

Type: string

type

The solver dependent type code for the entity.

Type: integer

typename

The solver dependent type name for the entity.

Type: string

vectorx

The x component of the unit vector in the global coordinate system.

Type: double

vectory

The y component of the unit vector in the global coordinate system.

Type: double

vectorz

The z component of the unit vector in the global coordinate system.

Type: double

The following data names are available for classic loads:

baselocation: The coordinates where the load on a component or set should display. Valid for hm_getvalue query only.; Also used to convert the load vector components into local values for non-rectangular coordinate systems.; Type: triple double
baselocationx: The x-coordinate where the load on a component or set should display.; Also used to convert the load vector components into local values for non-rectangular coordinate systems.; Type: double
baselocationy: The y-coordinate where the load on a component or set should display.; Also used to convert the load vector components into local values for non-rectangular coordinate systems.; Type: double
baselocationz: The z-coordinate where the load on a component or set should display.; Also used to convert the load vector components into local values for non-rectangular coordinate systems.; Type: double
comp1: The x component of the vector in the global coordinate system.; Type: double
comp2: The y component of the vector in the global coordinate system.; Type: double
comp3: The z component of the vector in the global coordinate system.; Type: double
component: Pointer to the component when the load is applied to a component.; Type: pointer
curveid: The ID of the curve defining the load magnitude when a curve has been used to define the load.; Type: integer
inputsystem: Pointer to the reference system.; Type: pointer
inputsystemid: The ID of the reference system.; Type: integer

local_comp1: The x component of the vector in the local coordinate system.; Type: double
local_comp2: The y component of the vector in the local coordinate system.; Type: double
local_comp3: The z component of the vector in the local coordinate system.; Type: double
local_vector: The load vector in the local coordinate system.; Type: triple double
local_vectorx: The x component of the unit vector in the local coordinate system.; Type: double
local_vectory: The y component of the unit vector in the local coordinate system.; Type: double
local_vectorz: The z component of the unit vector in the local coordinate system.; Type: double

location: The ID of the node where the load is applied. Valid for hm_getvalue query only.; Type: entity

magnitude: The magnitude of the vector; Type: double
mappedid: The ID of the original load on geometry.; Type: integer
node: Pointer to the node when the load is applied to a node.; Type: pointer
vector: The component of the unit vector. Valid for hm_getvalue query only.; Type: triple double
xscale: The x scale or time scale of the load curve when a curve has been used to define the load.; Type: double

The following data names are available for engineering loads:

compx: The dot product of the load vector projected on the global x axis.; Type: double
compy: The dot product of the load vector projected on the global y axis.; Type: double
compz: The dot product of the load vector projected on the global z axis.; Type: double
distribution_table_count: The number of rows of a non-uniform engineering load.; Type: unsigned integer
field: The field entity that stores the tabular load data.; Type: entity
location_unit_node: The nodes for which the data is stored in the table for a non-uniform engineering load.; Type: entity array
orient: The load orientation vector.; Type: triple double
orientx: The x component of the load orientation vector.; Type: double
orienty: The y component of the load orientation vector.; Type: double
orientz: The z component of the load orientation vector.; Type: double
resultant_magnitude: The resultant scalar component of the load vector in the global coordiante system.; Type: double

The following data names are available for LS-DYNA engineering loads:

activation_time: The time the imposed motion is activated (default 0.0).; Type: double
analysis_phase: Flag specifying phase of the analysis the velocities apply to for INITIAL_VELOCITY_GENERATION (type=6):; 0 – Velocities are applied immediately (default); 1 – Velocities are applied after reaching the start time; Type: integer
ang_vel_center: The rotational axis vector.; Type: triple double
angular_velocity: The angular velocity about the rotational axis (default 0.0).; Type: double
box_region_def: The box ID.; Type: entity
curveid: The load curve ID.; Type: entity
deactivation_time: Time imposed motion is removed (default 10²⁰).; Type: double
displayname: For the title name entry.; Type: string
dyn_relax_evolve_fn: The load curve ID during the dynamic relaxation phase.; Type: entity
entity_select_option: Flag that enables node selection for NY and NZ for INITIAL_VELOCITY_GENERATION (type=6).; Type: Boolean
exempt_node_init_trans_vel: The initial translational velocity of exempted nodes.; Type: triple double
exempt_node_init_rot_vel: The initial rotational velocity of exempted nodes.; Type: triple double
exempt_nodes: The node set ID containing nodes that are exempted from the imposed velocities.; Type: entity
init_rot_vel: The initial rotational velocity.; Type: triple double
init_vel_hierarchy: The option to control hierarchy of initial velocities.; 0 - *PART_INERTIA / *CONSTRAINED_NODAL_RIGID_BODY_INERTIA controls initial velocities (default); 1 - *INITIAL_VELOCITY_GENERATION controls initial velocities; Type: integer
init_vel_secondary_nodes_part: Flag for setting the initial velocities of secondary nodes and parts.; 0 - Secondary parts are ignored (default); 1 - Secondary parts and secondary nodes of the main parts will be assigned initial velocities like the main part; Type: integer
inputsystem: The coordinate system ID.; Type: entity
keyword_name: Flag that activates ID option.; Type: Boolean
load_body_opt: Angular velocity option. Valid options are RX, RY or RZ.; Type: string
load_dof: Applicable degrees-of-freedom for BOUNDARY_PRESCRIBED_MOTION (type=1):; 1 - x-translational degree-of-freedom; 2 - y-translational degree-of-freedom; 3 - z-translational degree-of-freedom; 4 - Translational motion in direction given by the VID. Movement on plane normal to the vector is permitted.; -4 - Translational motion in direction given by the VID. Movement on plane normal to the vector is not permitted.; 5 - x-rotational degree-of-freedom; 6 - y-rotational degree-of-freedom; 7 - z-rotational degree-of-freedom; 8 - Rotational motion about a vector parallel to vector VID. Rotation about the normal axes is permitted.; -8 - Rotational motion about a vector parallel to vector VID. Rotation about the normal axes is not permitted.; 9 - Rotation motion about axis parallel to the x-axis. Radial motion is not permitted.; -9 - Rotation motion about axis parallel to the x-axis. Radial motion is permitted.; 10 - Rotation motion about axis parallel to the y-axis. Radial motion is not permitted.; -10 - Rotation motion axis parallel to the y-axis. Radial motion is permitted.; 11 - Rotation motion about axis parallel to the z-axis. Radial motion is not permitted.; -11 - Rotation motion about axis parallel to the z-axis. Radial motion is permitted.; Type: integer
magnitude: The load curve scale factor (default 1.0).; Type: double
motion_rigid_local_option: Flag that activates the LOCAL option.; Type: Boolean
motion_type: Velocity/Acceleration/Displacement flag.; 0 - Velocity (rigid bodies and nodes); 1 - Acceleration (rigid bodies and nodes); 2 - Displacement (rigid bodies and nodes); 3 - Velocity versus displacement (rigid bodies only); 4 - Relative displacement (rigid bodies only); Type: integer
motion_vec_dir: The vector ID for BOUNDARY_PRESCRIBED_MOTION (type=1) for load_dof values 4 and 8.; Type: entity
nodal_rigid_body: The element ID of the constrained nodal rigid body.; Type: entity
part_set_overwrite_vel: The part set ID.; Type: entity
plane_axis_coord1: For BOUNDARY_PRESCRIBED_MOTION: Offset for DOF types 9 - 11 (y, z, x direction) (default 0.0).; Type: double
plane_axis_coord2: For BOUNDARY_PRESCRIBED_MOTION: Offset for DOF types 9 - 11 (z, x, y direction) (default 0.0).; Type: double
plane_node1: For INITIAL_VELOCITY_GENERATION: Node 1 of the rotational axis.; Type: entity
plane_node2: For INITIAL_VELOCITY_GENERATION: Node 2 of the rotational axis.; Type: entity
region_type: Region selection option.; 1 - Select part set or node set on entityid dataname; 2 - Select rigid body on rigid_part dataname; 0 - Velocity is applied on entire model; Type: unsigned integer
rgd_bdy_vel_opt_overwrite: For INITIAL_VELOCITY: Option to overwrite rigid body velocities.; 1 - Select part set entity on ‘part_set_overwrite_vel’ dataname; -1 - Overwrite velocities for all rigid bodies that have a center of gravity within box BOXID; -2 - Overwrite velocities for all rigid bodies; Type: integer
rigid_part: The part ID of the rigid body.; Type: entity
rigidbody_option: Flag that enables nodal rigid body selection.; Type: Boolean
set_type: Set type.; Type: unsigned integer
vector: The initial translational velocity.; Type: triple double
xcosine: X-direction cosine (default 0.0).; Type: double
ycosine: Y-direction cosine (default 0.0).; Type: double
zcosine: Z-direction cosine (default 0.0).; Type: double

The following data names are available for Radioss engineering loads:

curveid: The ID of the time function identifier curve.; Type: entity
displayname: The text for the title entry.; Type: string
distribution: The spring specification for IMPVEL_FGEO:; 0 - Spring part selection; 1 - Final node positions; Type: unsigned integer
inputsystem: The skew/frame identifier.; Type: entity
magnitude: The ordinate (velocity) scale factor for fct_ID (default 1.0).; Type: double
rad_dir: The direction X, Y, or Z for translation or XX, YY, or ZZ for rotation.; Type: string
rad_dmin: The distance between node ID N and node ID N', which are rigidly connected.; Type: double
rad_ebcs_c: The speed of sound (default 0.0).; Type: double
rad_ebcs_fscale_en: The energy scale factor (default 0.0).; Type: double
rad_ebcs_fscale_pr: The pressure scale factor (default 0.0).; Type: double
rad_ebcs_fscale_rho: The density scale factor (default 0.0).; Type: double
rad_ebcs_fscale_vx: The x velocity scale factor (default 0.0).; Type: double
rad_ebcs_fscale_vy: The y velocity scale factor (default 0.0).; Type: double
rad_ebcs_fscale_vz: The z velocity scale factor (default 0.0).; Type: double
rad_ebcs_lc: The characteristic length (default 0.0).; Type: double
rad_ebcs_r1: The linear resistance (default 0.0).; Type: double
rad_ebcs_r2: The quadratic resistance (default 0.0).; Type: double
rad_ebcs_rho: The initial density (default 0.0).; Type: double
rad_fct_en: The function identifier for energy.; Type: entity
rad_fct_l_id: The load time function identifier.; Type: entity
rad_fct_pr: The function identifier for pressure.; Type: entity
rad_fct_rho: The function identifier for density.; Type: entity
rad_fct_vx: The function identifier for x velocity.; Type: entity
rad_fct_vy: The function identifier for y velocity.; Type: entity
rad_fct_vz: The function identifier for z velocity.; Type: entity
rad_grquad_id: The quad groups on which the specific initial velocities are applied.; Type: entity
rad_grtria_id: The tria groups on which the specific initial velocities are applied.; Type: integer
rad_icoor: The coordinate system type:; 0 - Cartesian; 1 - Cylindrical; Type: integer
rad_inivel_type: Enables selection of INIVEL type:; GRID - Grid material velocity (only for ALE material); ROT - Rotational material velocity; T+G - Translational and grid material velocity *only for ALE material); TRA - Translational material velocity; Type: string
rad_node_id: The node identifier giving the final position of the node.; Type: entity
rad_rotational_velocity: The rotational velocity about the rotational axis.; Type: double
rad_sensor_id: The ID of the sensor entity.; Type: entity
rad_spring_part: The spring part identifier.; Type: entity
rad_system_input_type: The system input type:; 0 - Skew; 1 - Frame; Type: unsigned integer
rad_t0: The time duration.; Type: double
rad_tstart: The start time.; Type: double
rad_tstop: The stop time (default 10³⁰).; Type: double
vector: The velocity vector.; Type: triple double
xscale: The abscissa (time) scale factor for fct_IDT (default 1.0).; Type: double

Version History

2020 - New support for engineering loads. Added new data names compx, compy, compz, displayname, distribution, distribution_table_count, engineering_type, field, local_comp1, local_comp2, local_comp3, local_vector, local_vectorx, local_vectory, local_vectorz, location, location_unit_node, orient, orientx, orienty, orientz, rad_dir, rad_dmin, rad_ebcs_c, rad_ebcs_fscale_en, rad_ebcs_fscale_pr, rad_ebcs_fscale_rho, rad_ebcs_fscale_vx, rad_ebcs_fscale_vy, rad_ebcs_fscale_vz, rad_ebcs_lc, rad_ebcs_r1, rad_ebcs_r2, rad_ebcs_rho, rad_fct_l_id, rad_fct_en, rad_fct_pr, rad_fct_rho, rad_fct_vx, rad_fct_vy, rad_fct_vz, rad_icoor, rad_inivel_type, rad_node_id, rad_sensor_id, rad_spring_part, rad_system_input_type, rad_t0, rad_rotational_velocity, rad_tstart, rad_tstop and resultant_magnitude.

2020.1 - Added new data name solverkeyword.

2021.1 – Added new data names for LS-DYNA engineering loads: activation_time, analysis_phase, ang_vel_center, angular_velocity, box_region_def, curveid, deactivation_time, displayname, dyn_relax_evolve_fn, entity_select_option, exempt_node_init_rot_vel, exempt_node_init_trans_vel, exempt_nodes, init_rot_vel, init_vel_hierarchy,init_vel_secondary_nodes_part, inputsystem, keyword_name, load_body_opt, load_dof, magnitude,motion_rigid_local_option, motion_type, motion_vec_dir, nodal_rigid_body, part_set_overwrite_vel, plane_axis_coord1, plane_axis_coord2, plane_node1, plane_node2, region_type, rgd_bdy_vel_opt_overwrite, rigid_part, rigidbody_option, set_type, vector, xcosine, ycosine, and zcosine.

2021.1 - Added new data names moduleid, poolid, poolname, and solver_id.

2021.2 - Added new data names for Radioss engineering loads rad_grquad_id and rad_grtria_id. Added new data names internalname and solvername.