Output to the Data and Results Files

Abaqus/Standard analysis results can be written to the data (.dat) file. Element output, nodal output, contact surface output, energy output, modal output, and section output are available.

CONTACT PRINT
EL PRINT
ENERGY PRINT
MODAL PRINT
NODE PRINT
SECTION PRINT

Abaqus/Standard analysis results can be written to the results (.fil) file. Element output, nodal output, contact surface output, energy output, modal output, and section output are available.

CONTACT FILE
EL FILE
ENERGY FILE
MODAL FILE
NODE FILE
SECTION FILE

You can write Abaqus/Explicit analysis results to the selected results (.sel) file by specifying a results file output request in conjunction with element output, nodal output, and/or energy output requests, as explained below. A results file output request can appear only once per step but remains in effect in subsequent steps unless it is redefined.

You can convert the selected results file (job-name.sel) into the results (job-name.fil) file using the convert utility described in Obtaining results file output in Abaqus/Explicit and Abaqus/Standard and Abaqus/Explicit execution.

FILE OUTPUT
EL FILE
ENERGY FILE
NODE FILE

FILE OUTPUT, NUMBER INTERVAL=n, TIME MARKS=NO

FILE OUTPUT, NUMBER INTERVAL=n, TIME MARKS=YES

The following types of element variables are recognized for the purpose of defining output:

• “Element integration point” variables are associated with the integration points at which the material calculations are performed (for example, components of stress and strain). For beams and pipes defined in Abaqus/Standard with a general beam section, integration point variables are available only if the output section points were specified for the section (see Using a general beam section to define the section behavior). For first-order heat transfer elements the integration points are located at the corners of the element in heat capacitance calculations.

• “Element section point” variables are associated with the cross-section of a beam, pipe, or a shell (for example, bending moments and membrane forces on the section).

• “Whole element” variables are attributes of an entire element (for example, the total energy content of the element).

• “Whole element set” variables are attributes of an entire element set (for example, the current coordinates of the center of mass); these variables are available only in Abaqus/Standard.

The element variables that can be written to the data and results files are defined in Abaqus/Standard output variable identifiers and Abaqus/Explicit output variable identifiers.

Abaqus/Standard allows only complete sets of basic variables (for example, all of the stress or strain components) to be written to the results file. Individual variables (such as a particular stress component) cannot be selected and must be obtained by postprocessing. Abaqus/Standard element variables can be written to the data and results files at the integration points, at the centroid, averaged at the nodes, or extrapolated to the nodes.

In Abaqus/Explicit the complete stress or strain tensors can be written to the selected results file, or individual scalar variables such as equivalent plastic strain can be written. Abaqus/Explicit writes element variables to the results file only at the integration points where they are calculated.

You can specify the element set for which output is being requested. If you do not specify an element set, the output will be printed for all elements and, in Abaqus/Explicit, for all rebars in the model. In Abaqus/Standard output requests for rebars are governed separately, as discussed below.

EL PRINT, ELSET=element_set_name
EL FILE, ELSET=element_set_name

EL PRINT
list of output points
EL FILE
list of output points

EL PRINT, REBAR=rebar_name
EL FILE, REBAR=rebar_name

In Abaqus/Standard integration point variables and section variables can be written to the data and results files in four different positions. By default, output is provided at the integration points.

EL PRINT, POSITION=INTEGRATION POINTS
EL FILE, POSITION=INTEGRATION POINTS

EL PRINT, POSITION=CENTROIDAL
EL FILE, POSITION=CENTROIDAL

EL PRINT, POSITION=AVERAGED AT NODES
EL FILE, POSITION=AVERAGED AT NODES

EL PRINT, POSITION=NODES
EL FILE, POSITION=NODES

By default in Abaqus/Standard, summaries of element variables are printed in the data file. A summary of the maximum and minimum values is printed at the end of each column in an output table. The locations of the maximum and minimum values are also printed. You can choose to suppress this summary.

EL PRINT, SUMMARY=YES or NO

In Abaqus/Standard you can print the sum (total) of each column in an output table to the data file. Totals can be used, for example, to obtain a sum of all the energies in a set of elements. By default, these totals are suppressed.

EL PRINT, TOTALS=YES or NO

In Abaqus/Standard you can control the frequency of element output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

In Abaqus/Explicit the frequency of element output is controlled as described in Output frequency above.

EL PRINT, FREQUENCY=n 
EL FILE, FREQUENCY=n

For components of stress, strain, and similar material variables, 1, 2, and 3 refer to the directions in an orthogonal coordinate system. If a local orientation is not defined for the element, the stress/strain components are in the default directions defined by the convention given in Conventions: global directions for solid elements; surface directions for shell, membrane, and gasket elements; and axial and transverse directions for beam and pipe elements.

If a local orientation is associated with the element, the element output variable components are in the local directions defined by the orientation (see Orientations). In Abaqus/Standard you can request that the local directions be written to the results file if component output is requested for any variable (see Output of local directions to the results file below). In Abaqus/Explicit the local directions will always be written to the results file when tensor output is requested for any element variable. The local directions are written automatically to the output database file from both Abaqus/Standard and Abaqus/Explicit.

In large-displacement problems the local directions defined in the reference configuration are rotated into the current configuration by the average material rotation. See State storage for details.

You can control element output during natural frequency extraction (Natural frequency extraction), complex eigenvalue extraction (Complex eigenvalue extraction), and eigenvalue buckling analysis (Eigenvalue buckling prediction) by specifying the first and last mode numbers for which output is required. By default, the first mode number is 1 and the last mode number is N, where N is the number of modes extracted. If you specify the first mode number, the default value for the last mode number is M, where M is the value specified for the first mode number.

EL PRINT, MODE=m, LAST MODE=n
EL FILE, MODE=m, LAST MODE=n

In Abaqus/Standard the printed output of variables is arranged in tables in the data file. For element variables, each row of a table corresponds to a particular location: an element, a node, a section point within an element, or an integration point. The rows that will appear in a particular table are defined by choosing an element set and, possibly, locations within each element in the set.

Each table is defined by a data line of the element output request, which specifies the variables to appear in that table. There is no limit to the number of tables that can be defined. The first columns of a table define the location—the element or node number, integration point number, etc. You choose which data will appear in the remaining columns; up to 9 variables (columns) can appear in a table. For example, output variables S and E cannot be requested on the same data line in a three-dimensional analysis because that would produce 12 columns of output. If all of the entries in a row are zero, the row is not printed.

Each table can contain only one type of output variable (whole element, section, or integration point); one type of element; and only one type of section definition. If an element output request to the data file includes more than one type of output variable, element, or section definition, Abaqus/Standard will split the output automatically into the necessary number of individual tables. All of the tables defined by the first data line of the output request will be printed, then all of the tables defined by the second data line, etc.

An element header record (the type 1 record described in Results file output format) is created for each line of requests for each integration point and section point in an element. In addition to the element header record, a direction record (record type 85) can be written in Abaqus/Standard when complete stress or strain tensor output is requested (see below). In Abaqus/Explicit a direction record is always written when complete stress or strain tensor output is requested.

For Abaqus/Standard file output requests with multiple variables, it is advantageous to specify as many variables as possible on each data line of the element output request (up to 16). By keeping the number of lines of requests to a minimum, extra type 1 and type 85 records are avoided and the size of the results file may be reduced substantially. This is not an issue in Abaqus/Explicit. Element variables must be of the same “type” (element integration point variable; element section variable; whole element variable; etc.) to be entered on a single line—see About Output. In Abaqus/Standard if all results in a file output record are zero, the record is not written to the results file.

EL FILE, DIRECTIONS=YES

If you do not specify an element output request to the results file in a step (or in any previous step of the analysis), no element output will be written to the results file; similarly, if you do not specify an element output request to the data file (available only in Abaqus/Standard) in a step (or in any previous step of the analysis), no element output will be written to the data file.

The nodal variables that can be written to the data and results files are defined in the “Nodal variables” portion of Abaqus/Standard output variable identifiers and Abaqus/Explicit output variable identifiers.

Abaqus allows only complete sets of basic variables (for example, all of the displacement components) to be written to the results file. Individual variables (such as a particular displacement component) cannot be selected and must be obtained by postprocessing.

You can specify the node set for which output is being requested. If you do not specify a node set, the output will be printed for all nodes in the model.

NODE PRINT, NSET=node_set_name
NODE FILE, NSET=node_set_name

By default in Abaqus/Standard, summaries of nodal variables are printed in the data file. A summary of the maximum and minimum values is printed at the end of each column in an output table. The locations of the maximum and minimum values are also printed. You can choose to suppress this summary.

NODE PRINT, SUMMARY=YES or NO

In Abaqus/Standard you can print the sum (total) of each column in an output table to the data file. Totals can be used, for example, to sum reaction forces at the nodes. By default, these totals are suppressed.

NODE PRINT, TOTALS=YES or NO

In Abaqus/Standard you can control the frequency of nodal output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

In Abaqus/Explicit the frequency of nodal output is controlled as described in Output frequency above.

NODE PRINT, FREQUENCY=n
NODE FILE, FREQUENCY=n

For nodal variables 1, 2, and 3 refer to the global directions X, Y, and Z, respectively. For axisymmetric elements 1 and 2 refer to the global directions r and z.

In Abaqus/Standard components of nodal variables such as reaction forces are output in the global directions unless a local coordinate system has been defined at a node (see Transformed coordinate systems). In this case you can specify whether output is desired in global or local directions. The local directions defined by the nodal transformation cannot be written to the results file.

The data in the Abaqus/Explicit selected results file are always output in the global directions, even if a local coordinate system has been defined at a node.

NODE PRINT, GLOBAL=YES
NODE FILE, GLOBAL=YES

NODE PRINT, GLOBAL=NO
NODE FILE, GLOBAL=NO

You can control nodal output during natural frequency extraction, complex eigenvalue extraction, and eigenvalue buckling analysis by specifying the first and last mode numbers for which output is required, as described above for element output.

NODE PRINT, MODE=m, LAST MODE=n
NODE FILE, MODE=m, LAST MODE=n

In Abaqus/Standard the printed output of variables is arranged in tables by node set in the data file. For nodal variables each row of a table corresponds to an individual node.

Each table is defined by a data line of the nodal output request, which specifies the variables to appear in that table. There is no limit to the number of tables that can be defined. The first column of each table is the node number. You choose the variables to appear in the remaining columns; up to nine variables (columns) can appear in a table. If all of the entries in a row are zero, the row is not printed. Displacement, velocity, and acceleration components less than a relative tolerance (equal to 100 times the machine precision times the current maximum value in the model) are treated as zero.

There is no header or direction record for nodes, so it makes little difference whether items are requested on a single line or multiple lines. In Abaqus/Standard if all results in a record are zero, the record is not written to the results file.

If you do not specify a nodal output request to the results file in a step (or in any previous step of the analysis), no nodal output will be written to the results file; similarly if you do not specify a nodal output request to the data file (available only in Abaqus/Standard) in a step (or in any previous step of the analysis), no nodal output will be written to the data file.

Abaqus/Standard may generate inaccurate external work (ALLWK) in the presence of a concentrated follower load that rotates with time (see Specifying concentrated follower forces). This problem may occur in both static and implicit dynamic analyses and may result in an inaccurate total energy (ETOTAL) history output. Other results (displacements, stresses, strains, etc.) are not affected. The inaccuracy is due to the fact that the increment of work is calculated using the direction of the concentrated load at the end of the increment instead of using an average load over the increment.

When energy output is requested, all of the total energy quantities listed in Abaqus/Standard output variable identifiers or Abaqus/Explicit output variable identifiers are output; the variables cannot be selected individually.

In Abaqus/Standard you can specify the element set for which total energy output is being requested. In this case the energies are summed for all the elements in the specified set. You cannot specify an element set for the following procedures:

• Transient modal dynamic analysis

• Mode-based steady-state dynamic analysis

• Response spectrum analysis

• Random response analysis

If you do not specify an element set, the total energies for the whole model will be output. If total energy output for both the whole model and for different element sets is desired, the energy output requests must be repeated; once without a specified element set to request energy output for the whole model and once for each specified element set.

In Abaqus/Explicit you cannot specify selected element sets for an energy output request; the total energies for the whole model will always be output.

ENERGY PRINT, ELSET=element_set_name
ENERGY FILE, ELSET=element_set_name

In Abaqus/Standard you can control the frequency of energy output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

In Abaqus/Explicit the frequency of energy output is controlled as described in Output frequency above.

ENERGY PRINT, FREQUENCY=n
ENERGY FILE, FREQUENCY=n

Energy output requests must be included for total energy output to be written to the data and results files; no default output is provided.

The modal variables that can be written to the data and results files are defined in the “Modal variables” portion of Abaqus/Standard output variable identifiers.

You can control the frequency of modal output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

MODAL PRINT, FREQUENCY=n
MODAL FILE, FREQUENCY=n

Modal output requests must be included for modal results to be written to the data and results files; no default output is provided.

The following types of surface variables are recognized for the purpose of defining output:

• “Slave node” variables are associated with the integration points at which the material calculations are performed (for example, the contact stress).

• “Whole surface” variables are attributes of an entire slave surface (for example, the total force due to contact pressure).

The surface variables that can be written to the data and results files are listed in the “Surface variables” portion of Abaqus/Standard output variable identifiers.

You can select the master and slave surfaces for which output is required, and you can specify a subset of slave nodes for output in addition to the master and slave surfaces or independently. If no surfaces or slave nodes are specified, surface variables are written for all the contact pairs in the model. If you specify the slave surface but not the master surface, output is given for all contact pairs that involve the specified slave surface.

CONTACT PRINT, MASTER=master, SLAVE=slave, NSET=node_set
CONTACT FILE, MASTER=master, SLAVE=slave, NSET=node_set

By default, summaries of surface variables are printed in the data file. A summary of the maximum and minimum values is printed at the end of each column in an output table. The locations of the maximum and minimum values are also printed. You can choose to suppress this summary.

CONTACT PRINT, SUMMARY=YES or NO

You can print the sum (total) of each column in an output table to the data file. By default, these totals are suppressed.

CONTACT PRINT, TOTALS=YES or NO

You can control the frequency of surface output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

CONTACT PRINT, FREQUENCY=n
CONTACT FILE, FREQUENCY=n

Surface output requests must be included for surface variables associated with contact pairs to be written to the data and results files; no default output is provided.

If a surface output request is defined without any specified output variables, the following variables will be written to the data and results files by default:

• For contact analysis, contact pressure (CPRESS), frictional shear stresses (CSHEAR), contact opening (COPEN), and relative tangential motions (CSLIP); see About contact pairs in Abaqus/Standard.

• For heat transfer analysis, heat flux per unit area (HFL), heat flux (HFLA), time integrated HFL (HTL), and time integrated HFLA (HTLA); see Thermal contact properties.

• For coupled thermal-electrical analysis, HFL, HFLA, HTL, HTLA, electrical current per unit area (ECD), electrical current (ECDA), time integrated ECD (ECDT), and time integrated ECDA (ECDTA); see Electrical contact properties.

• For coupled pore fluid-mechanical analysis, CPRESS, CSHEAR, COPEN, CSLIP, pore fluid volume flux per unit area (PFL), pore fluid volume flux (PFLA), time integrated PFL (PTL), and time integrated PFLA (PTLA); see Pore fluid contact properties.

• For crack propagation analysis, there are no default output quantities; bond failure quantities must be requested explicitly; see Crack propagation analysis.

Printed output of variables is arranged in tables. Each table is defined by a data line of the surface output request, which specifies the variables to appear in that table. Each table can contain only one type of output variable (slave node or whole surface). For example, output variables CSTRESS and CFN cannot be requested on the same data line. For the slave node type of output, each row of a table corresponds to a node on the slave surface. The rows that will appear in a particular table will be limited to the node set specified in the output request. The first column of each table defines the location (the node number). The remaining columns contain variables such as contact pressure, frictional shear stresses, contact opening, and relative tangential (slip) motions. For the whole surface type of output, each row of a table corresponds to an entire slave surface. If all of the variables in a row of a table are zero, the row is not printed.

If a contact output request refers to more than one contact pair, a separate table will be generated for each contact pair. All of the tables defined by the first data line of the output request will be printed, then all of the tables defined by the second line, etc.

A contact output request record (the type 1503 record described in Results file output format) is created for each output request. For the slave node type of output, this record is followed by several node header records, each of which contains a node on the slave surface. Each node header record is followed by records that contain output variables. The output will be limited to the node set specified in the output request. For the whole surface type of output, the type 1503 record is followed by only one type 1504 node header record with a node number zero. The node header record is followed by records containing the requested output variables.

If a contact output request refers to more than one contact pair, a separate contact output request record is generated for each contact pair.

Section output requests are available only for sections defined using element-based surfaces (see Element-based surface definition). Consequently, the sections must be defined using faces of continuum elements although other types of elements (beams, membranes, shells, springs, dashpots, etc.) can be attached to the section.

Calculation of accumulated quantities on the section (such as the total force) involves nodal quantities associated with elements on one side of the section only. Therefore, the surface definition should use elements only from one side of the section (the “base elements,” as defined in Prescribed Assembly Loads), thus precisely identifying the side from which accumulated quantities are computed.

Since the section usually cuts through the mesh in a typical section output request, automatic generation of the surface cannot be used. Specifying the element faces gives exact control over which element faces form the surface, which is essential when defining a cross-section through a solid body.

You must specify the name of the surface for which output is being requested.

Surfaces that are defined in a restart analysis can be used only for section output requests. The newly defined surface cannot be used for any other purpose (such as a contact pair or pre-tension section definition).

SECTION PRINT, NAME=section_name, SURFACE=surface_name
SECTION FILE, NAME=section_name, SURFACE=surface_name

HEADING
Section print example
…
SURFACE, NAME=surface_name
Data lines that specify the elements and their associated faces to define the 
surface section
…
STEP
…
SECTION PRINT, NAME=section_name, 
SURFACE=surface_name, …
…
END STEP

RESTART, READ, …
…
SURFACE, NAME=surface_name
Data lines that specify the elements and their associated faces to define the 
surface section
…
STEP
…
SECTION PRINT, NAME=section_name, 
SURFACE=surface_name, …
…
END STEP

You can specify the choice of coordinate system in which the section output is desired. By default, the components of vector quantities associated with the section are obtained with respect to the global system of coordinates. Alternatively, you can specify that output is desired in a local system as defined below.

SECTION PRINT, NAME=section_name, SURFACE=surface_name, 
AXES=GLOBAL or LOCAL
SECTION FILE, NAME=section_name, SURFACE=surface_name, 
AXES=GLOBAL or LOCAL

You can allow Abaqus/Standard to define the local system, or you can specify it directly.

SECTION PRINT, NAME=section_name, SURFACE=surface_name, AXES=LOCAL
SECTION FILE, NAME=section_name, SURFACE=surface_name, AXES=LOCAL

User-specified local system

A user-specified local system is defined by specifying the origin and the directions of the axes. You can specify the origin (anchor point) by giving a node number or by specifying the coordinates of the anchor point.

In two-dimensional and axisymmetric cases the local 2-direction is defined by specifying either a predefined node number or the coordinates of a point (point a) on the local 2-direction. The local 1-direction is then obtained by rotating the local 2-axis clockwise by 90° about the anchor point (see Figure 1). If node numbers are used to define the anchor point or the local directions, they must be connected to the mesh.

Figure 1. User-defined local coordinate system.

In three-dimensional cases either two predefined nodes or the coordinates of two points can be used to specify the local directions. A rectangular Cartesian coordinate system is then defined by its origin (the anchor point) and these two points. The first point (point a) must lie on the local 2-direction, and the second (point b) must be in the local 2–3 plane on the side of the local 3-direction. Although it is not necessary, it is intuitive to select the second point such that it is on or near the local 3-direction (see Figure 1).

If you do not specify the anchor point of the local system, it is taken to be the centroid of the projection of the surface on the fitted line or plane. If you do not specify the directions of the axes, the local system will be anchored at the specified anchor point and its axes will be parallel to the default axes of the projected surface. If neither the anchor point nor the directions are defined, the default local system will be used.

In large-deformation analyses the surface section may rotate significantly during the deformation. By default, when output is requested in a local coordinate system, the system rotates with the average rigid body motion of the elements used to define the surface section (i.e., the local system and the output are updated during the analysis). The anchor point and local directions must then be specified relative to the undeformed configuration. You can choose to obtain vector output in the original local coordinate system instead. This choice is irrelevant in steps in which geometric nonlinearities are not considered.

Input File Usage

Use either of the following options to specify the local coordinate system directly:

SECTION PRINT, NAME=section_name, SURFACE=surface_name, 
AXES=LOCAL, UPDATE=YES or NO
anchor point definition
axes definition
SECTION FILE, NAME=section_name, SURFACE=surface_name, 
AXES=LOCAL, UPDATE=YES or NO
anchor point definition
axes definition

You can control the frequency of section output by specifying the output frequency in increments. Unless a frequency of zero is specified to suppress output, the variables will always be output at the last increment of the step.

SECTION PRINT, NAME=section_name, SURFACE=surface_name, FREQUENCY=n
SECTION FILE, NAME=section_name, SURFACE=surface_name, FREQUENCY=n

Printed output is arranged in tables. The first line of the table contains the name of the requested output variable (see Abaqus/Standard output variable identifiers), and the second line contains the corresponding value. If a section output request is defined without any specified output variables, all appropriate variables associated with the current analysis type are output.

If several section output requests to the data file are encountered in one particular step, separate tables will be created for each request. Each table has a header denoting the name of the section and the name of the surface used. In addition, if the output is requested in a local coordinate system, the global coordinates of the anchor point and the cosine directions of the local axes are output.

Several section output records (record numbers 1580–1591 in Results file output format) are output for each section output request to the results file. The actual collection of records to be written to the results file depends on the number of valid output requests. If a section output request is defined without any specified output variables, all records relevant to the current analysis type are stored in the results file.

Vector output associated with section output requests consists of the total force (SOF), the total moment (SOM), and the center of forces (SOCF). Output variable SOF is computed as a vector sum of the stress-based (internal) nodal forces of the nodes in the surface.

Output variable SOM is computed with respect to the origin of the coordinate system considered. Thus, if the output is requested in the global coordinate system, the total moment is computed about the global origin; if the output is requested in a local coordinate system, the moment is computed about the current anchor point of the local system. The coordinates of the current anchor point may change during the analysis if the local coordinate system is updated. Output variables SOF and SOM are both reported in the coordinate system considered.

The center of forces SOCF is computed as the closest point to the centroid of the section through which the total force SOF acts. SOCF is always reported in the global coordinate system. If the total force vector is equal to zero, the centroid of the section is reported as the center of forces SOCF.

The total moment vector, SOM, will not necessarily equal the cross product of the center of force vector, SOCF, and total force vector, SOF. Forces acting on two different points of the section may have components acting in opposite directions, such that these force components generate a net moment but not a net force; therefore, the total moment may not arise entirely from the resultant force.

Scalar output associated with a section output request consists of the area of the defined section (SOAREA), the total heat flux (SOH) in heat transfer analysis, the total current (SOE) in electrical analysis, the total mass flow (SOD) in mass diffusion analysis, and the total pore fluid volume flux (SOP) in couple pore fluid diffusion-stress analysis. These output variables are computed as the algebraic sum of the scalar internal nodal fluxes (work-conjugate to the associated primary solution variables) of the nodes in the surface. For example, in heat transfer analysis the total heat flux (SOH) is the sum of the NFLUX values at the nodes on the surfaces.

Section output requests are subject to the following limitations:

• Section output requests are available only for sections defined by an element-based surface. Thus, they can be used only for sections along faces of continuum elements.

• When defining the section, elements on only one side of the section must be used. Abaqus/Standard identifies all elements attached to the surface on this side and computes the section output variables as in a free-body diagram.

• The defined section must cut completely through the mesh, form a closed surface, or be on the exterior of the body. Figure 2 presents some typical cases of valid surfaces. If the section cuts only partially through the mesh, a valid free-body diagram cannot be isolated (see Figure 3) and incorrect answers may be computed. Abaqus/Standard will attempt to identify the invalid cases and will issue error or warning messages.

  Figure 2. Valid section definitions.
  
  
  Figure 3. Invalid section definitions.
  
  

• Elements attached to the section can be on either side of the surface but must not cross the defined section. Figure 3 presents a few invalid cases. In most cases Abaqus/Standard will successfully identify elements that cross the surface, and warning messages will be issued. The elements will then not be considered in the calculation of the section variables.

• For section output purposes, Abaqus/Standard will ignore the elements attached to the section for which it cannot establish whether they belong to one side or the other of the section (e.g., SPRING1 elements).

• Section output requests cannot be specified within a substructure.

• Section output requests cannot be specified in random response analyses.

• The total force and the total moment in the section are computed based only on the stresses (internal forces) in the identified elements. Thus, inaccurate results may be obtained if distributed body loads are present in these elements since their effect on the total force in the section is not included. Common examples are the inertial loading in dynamic analyses, gravity loads, distributed body forces, and centrifugal loads. In these cases the total force in the section may depend on the choice of elements used to define the section as illustrated in Figure 4(a). Assuming that gravity loading is the only active load, the element stresses will be different in the two elements. Hence, if the same section is defined first using element 1 and then using element 2, different answers for the total force will be obtained. In a similar way the effects of any distributed body fluxes (heat, electrical, etc.) prescribed in the identified elements are not included.

  Figure 4. Total force in the section.
  
  

• Depending on which side of the surface is used to define the section, different answers will be obtained in analyses similar to the case illustrated in Figure 4(b). Assuming a static analysis with the concentrated loads shown in the figure being the only active loads, a zero total force is reported if the section is defined using element 1 and a nonzero force equal to the sum of the concentrated loads is obtained if the section is defined using element 2.