Difference between revisions of "FEA Periodic Boundaries"

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[[File:Periodic.jpg|right]]
[[File:Periodic.jpg|right]]
The figure on the right shows a mesh of width &Delta;x and height &Delta;x in which the left and right edges are parallel to the <tt>y</tt> axis and each node on the left edge corresponds to a node on the right edge at the same <tt>y</tt> coordinate. If this structure is an element on a large object and periodic in the <tt>x</tt> direction, it means the the strains are periodic or that:
The figure on the right shows a mesh of width &Delta;x and height &Delta;y in which the left and right edges are parallel to the <tt>y</tt> axis and each node on the left edge corresponds to a node on the right edge at the same <tt>y</tt> coordinate. If this structure is a piece on a large object that is periodic in the <tt>x</tt> direction only, it means that the strains are periodic or that:


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
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&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>u_i(\Delta x,y_i) = u_i(0,y+i) + k_1 + k_2 y_i \qquad {\rm for}\ i=1,\ {\rm to}\ n</math>
<math>u_i(\Delta x,y_i) = u_i(0,y_i) + k_1 + k_2 y_i \qquad {\rm for}\ i=1,\ {\rm to}\ n</math>


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>v_i(\Delta x,y_i) = v_i(0,y+i) + v_1(\Delta x,y_1) - v_1(0,y_1) \qquad {\rm for}\ i=2,\ {\rm to}\ n</math>
<math>v_i(\Delta x,y_i) = v_i(0,y_i) + v_1(\Delta x,y_1) - v_1(0,y_1) \qquad {\rm for}\ i=2,\ {\rm to}\ n</math>


These conditions are solved by using FEA method of Lagrangian multipliers. All <tt>x</tt> displacements on the right are replaced by constraints as are all <tt>y</tt> (except v_1(&Delta;x,y_1), which remains a degree of freedom. In addition, k<sub>1</sub> and k<sub>2</sub> are introduced as two new degrees of freedom. It is better to rewrite these degrees of freedom using
These conditions are solved by using FEA method of Lagrange multipliers. All <tt>x</tt> displacements on the right are replaced by constraints as are all <tt>y</tt> (except <math>v_1(\Delta x,y_1)</math>, which remains a degree of freedom). In addition, k<sub>1</sub> and k<sub>2</sub> are introduced as two new degrees of freedom. It is better to rewrite new degrees of freedom using


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>k_1 + k_2 y_i = \Delta u + {du\over dy}(y_i - \left\langle y\right\rangle)</math>
<math>k_1 + k_2 y_i = \Delta u_n + {\Delta u_s\over \Delta y}(y_i - \left\langle y\right\rangle)</math>


where <<tt>y</tt>> is the mean <tt>y</tt> on the edges. Physically, &Delta;u the mean displacement jump across the modeled object, which results in an average <tt>x</tt> direction strain:
where <<tt>y</tt>> is the mean <tt>y</tt> on the edges. Physically, &Delta;u<sub>n</sub> is the mean displacement jump in the x direction across the modeled object, which results in an average <tt>x</tt> direction strain:


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \varepsilon_{xx}\right\rangle = {\Delta u\over \Delta x}</math>
<math>\left\langle \varepsilon_{xx}\right\rangle = {\Delta u_n\over \Delta x}</math>


Physically du/dy is the slope (or rotation) of the right edge relative to the left edge. Like nodal displacements, these new constants resulting from periodic boundary conditions can be degrees of freedom (''i.e.'', output of the analysis) or can be inputs (''e.g.'', boundary conditions that impose an average strain or relative rotation to the edges)
Similarly, &Delta;u<sub>s</sub> the shear jump in the x direction or the difference in x direction jumps at the top and bottom of the object. Like nodal displacements, these new terms resulting from periodic boundary conditions can be degrees of freedom (''i.e.'', output of the analysis) or can be inputs (''e.g.'', boundary conditions that impose an average stretch or shear displacement to the edges).


Using the same analysis on problems that are periodic only in the <tt>y</tt> (or the <tt>Z</tt> of axisymmetric analysis) give a series of constraints to displacements on the nodes at the top of the object relative to the displacements on the bottom of the object. The new constraints lead to two new degrees of freedom - &Delta;v and dvdx. Physically, &Delta;v is the mean displacement jump across the modeled object, which results in an average <tt>y</tt> direction strain:
Using the same analysis on problems that are periodic only in the <tt>y</tt> (or the <tt>Z</tt> of axisymmetric analysis) direction gives a series of constraints for displacements on the nodes at the top of the object relative to the displacements on the bottom edge. The new constraints lead to two more degrees of freedom - &Delta;v<sub>n</sub> and &Delta;v<sub>s</sub>. Physically, &Delta;v<sub>n</sub> is the mean displacement jump across the modeled object, which results in an average <tt>y</tt> direction strain:


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \varepsilon_{yy}\right\rangle = {\Delta v\over \Delta y}</math>
<math>\left\langle \varepsilon_{yy}\right\rangle = {\Delta v_n\over \Delta y}</math>


Physically dv/dx is the slope (or rotation) of the top edge relative to the bottom edge.
Similarly, &Delta;v<sub>s</sub> the shear jump in the y direction or the difference in y direction jumps at the left and right of the object.


Finally, if the problem is periodic in both direction, the four new degrees of freedom relate to average axial strains (as defined above for each direction) and to average shear strain by:
If both directions are periodic, the analysis needs some modifications. The general displacement constraints between left and right or top and bottom edges can be written:


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \gamma_{xy}\right\rangle = {1\over \Delta y}{du\over dy} + {1\over \Delta x}{dv\over dx}</math>
<math>u_i(\Delta x,y_i) = u_i(0,y_i) + \left\langle \varepsilon_{xx}\right\rangle \Delta x = u_i(0,y_i) + \Delta u_n</math>


For axisymmetric problems, the model cannot be periodic in the <tt>R</tt> direction. It can be periodic in the <tt>Z</tt> direction, but to maintain periodicity in the hoop stress (&epsilon;<sub>&theta;&theta;</sub>) to top and bottom edges must remain aligned. In other words, the rotational degree of freedom (dw/dr) must be zero (i.e., it is not a degree of freedom). The average axial strain is related to &Delta;w or the displacement drop in the vertical direction:
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>v_i(\Delta x,y_i) = v_i(0,y_i) + \left({\left\langle\gamma_{xy}\right\rangle\over 2} - \omega\right) \Delta x = v_i(0,y_i)  + \Delta v_s</math>
 
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>u_i(x_i,\Delta y) = u_i(x_i,0) + \left({\left\langle \gamma_{xy}\right\rangle\over 2} + \omega\right) \Delta y = u_i(x_i,0) + \Delta u_s</math>


&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \varepsilon_{ZZ}\right\rangle = {\Delta w\over \Delta Z}</math>
<math>v_i(x_i,\Delta y) = v_i(x_i,0) + \left\langle \varepsilon_{yy}\right\rangle \Delta y  = v_i(x_i,0) + \Delta v_n</math>
 
where &omega; is a rigid body rotation. The average normal strains are as above. The average shear strain is
 
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \gamma_{xy}\right\rangle = {\Delta u_s\over \Delta y} + {\Delta v_s\over \Delta x}</math>
 
For axisymmetric problems, the model cannot be periodic in the <tt>R</tt> direction. It can be periodic in the <tt>Z</tt> direction, but to maintain periodicity in the hoop stress (&epsilon;<sub>&theta;&theta;</sub>), the top and bottom edges must not rotate. In other words, the shear stretch (&Delta;v<sub>s</sub>) must be zero (''i.e.'', it is not a degree of freedom). The average axial strain is related to &Delta;w<sub>n</sub> or the displacement jump in the vertical direction:
 
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>\left\langle \varepsilon_{ZZ}\right\rangle = {\Delta w_n\over \Delta Z}</math>


== Input Commands ==
== Input Commands ==
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In scripted files, you set up periodic boundary conditions with one or two <tt>Periodic</tt> commands:
In scripted files, you set up periodic boundary conditions with one or two <tt>Periodic</tt> commands:


  Periodic (dir),<(dof1),(value1)>, <(dof2),(value2)>
  Periodic (dir),<(dof1),(value1)>,<(dof2),(value2)>


In <tt>XML</tt>, the one or two commands, which must be in the <tt><GridBCs</tt> section, are:
In <tt>XML</tt>, the one or two commands, which must be in the [[FEA Boundary Conditions#XML Input Files|<tt><GridBCs></tt> block]], are:


  <Periodic dof='(dir)' delta='(value1)' slope='(value2)'/>
  <Periodic dof='(dir)' delta='(value1)' slope='(value2)'/>
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* <tt>(dir)</tt> defines the periodic direction. [[NairnFEA]] allows periodicity in the <tt>x</tt> direction only, in the <tt>y</tt> direction only, or in both the <tt>x</tt> and <tt>y</tt> directions. For axisymmetric problems, periodicity is allowed in the <tt>Z</tt> direction only.
* <tt>(dir)</tt> defines the periodic direction. [[NairnFEA]] allows periodicity in the <tt>x</tt> direction only, in the <tt>y</tt> direction only, or in both the <tt>x</tt> and <tt>y</tt> directions. For axisymmetric problems, periodicity is allowed in the <tt>Z</tt> direction only.
Pairs of subsequent arguments specify options to the periodic calculations. In periodic calculations, the displacements on the two edges must be related by a translation and a rotation or a translation and shear. If nothing is specified, the translation and rotation or shear are degrees of freedom in the problem. Alternatively, you can specify them with the options:
* The optional <tt>(dof1),(value1)</tt> and <tt>(dof2),(value2)</tt> in scripted files can fix one or two periodic boundary degrees of freedom. In each pair, the <tt>dof</tt> is the degree or freedom and <tt>value</tt> is the setting. The options for <tt>dof</tt> are:
Delta: defines the translation or displacement jump between the two sides of the periodic direction (entered in mm). When applied to the x direction, the global average strain is <εxx> = Delta/Δx. When applied to the y direction, the global average strain is <εyy> = Delta/Δy. When applied to the z direction in axisymmetric analyses, the global average strain is <εzz> = Delta/Δz. Here Δx, Δy, and Δz are the specimen lengths in those directions.
*# <tt>Delta</tt> to set the displacement jump in that direction (in [[ConsistentUnits Command#Legacy and Consistent Units|length units]]). When applied to the <tt>x</tt> direction, the global average strain is <ε<sub>xx</sub>> = <tt>Delta</tt>/Δx. When applied to the <tt>y</tt> direction, the global average strain is <ε<sub>yy</sub>> = <tt>Delta</tt>/Δy. When applied to the <tt>Z</tt> direction in axisymmetric analyses, the global average strain is <ε<sub>zz</sub>> = <tt>Delta</tt>/Δz. Here Δx, Δy, and Δz are the specimen lengths in those directions.
Slope: When periodic in only one direction, Slope defines the rotation or relative slopes between the two sides of the periodic direction (dimensionless). When periodic in both x and y directions, Slope is a synonym for Shear (see below). For axisymmetric analyses, physical contraints require the slope to be zero. If you do not set it, it will automatically be set to zero for you.
*# <tt>Slope</tt> defines the relative edge slopes between the two sides when there is one periodic direction (dimensioness). It is &Delta;u<sub>s</sub>/&Delta;y for <tt>x</tt> direction only and &Delta;v<sub>s</sub>/&Delta;x for <tt>y</tt> (or <tt>Z</tt>) direction only.
Shear: When periodic in both x and y directions, Shear defines a component of average shear displacement. For #1 = x, Shear gives the x-direction displacement jump in the y direction of the specimen (dudy). For #2 = y, Shear gives the y-direction displacement jump in the x direction of the specimen (dvdx). The average shear strain is <γxy> = dudy/Δy + dvdx/Δx. Here Δx and Δy are the specimen lengths in those directions. When periodic in only one direction, Shear is a synonym for Slope (see above).
*# <tt>Shear</tt> defines the shearing displacement jump difference between the two sides of the periodic direction (in [[ConsistentUnits Command#Legacy and Consistent Units|length units]]) when both directions are periodic. It is &Delta;u<sub>s</sub> for <tt>x</tt> direction setting and &Delta;v<sub>s</sub> for <tt>y</tt> (or <tt>Z</tt>) direction setting. When periodic in both <tt>x</tt> and <tt>y</tt> directions, the average shear strain is <γ<sub>xy</sub>> = <tt>ShearX</tt>/Δy + <tt>ShearY</tt>/Δx. Here Δx and Δy are the specimen lengths in the two directions, <tt>ShearX</tt> is &Delta;u<sub>s</sub>, and <tt>ShearY</tt> is &Delta;v<sub>s</sub>.
The <code>dof</code> attribute defines the periodic direction. It must be <code>x</code> (or 1) or <code>y</code> (or 2) or <code>z</code> (or 3). The <code>delta</code>, <code>slope</code>, and <code>shear</code> attributes let you specify an average displacement jump, rotation, and/or shear between the two ends in the periodic direction(s). If any are left unspecified, they will be degrees of freedom. When specified, they correspond to globally applied strains or rotation. The meanings of the parameters are slightly different depending on whether just one direction or both directions are periodic:
* In <tt>XML</tt> files, optional <tt>(value1)</tt> and <tt>(value2)</tt> set the displacement jump and rotation using <tt>delta</tt> and <tt>slope</tt>, <tt>shear</tt> attributes.
 
For periodicity to work, the edges of the specimen on the two ends of the periodic direction(s) must be orthognal to that direction, they must each have the same number of nodes, and the orthogonal coordinate (''e.g.'', the <tt>y</tt> coordinate for <tt>x</tt> periodicity, the <tt>x</tt> coordinate for <tt>y</tt> periodicity, or the <tt>R</tt> coordinate for <tt>Z</tt> periodicity) of each node on one side must match the corresponding node on the other side.
 
Setting the periodic degrees of freedom for <tt>Delta</tt>, <tt>Slope</tt>, and <tt>Shear</tt> are optional. If they are not set, they are degrees of freedom in the problem (and can be found from output results). If they are set as boundary conditions, they can determine the average normal strains, edge rotations, and average shear strains. Finally, scripted commands can use <tt>Slope</tt> as a synonym from <tt>Shear</tt> and <tt>XML</tt> command can use a <tt>slope</tt> attribute as a synonym for the <tt>shear</tt> attribute. The code defines the appropriately condition depending on whether one or two directions are made periodic.


== Notes ==
== Notes ==


# Adding periodicity will greatly increase the bandwidth of the problem. A Resequence Command can be used, but is unlikely to help much. Instead, only use periodic conditions if they are needed to solve the problem.
# Adding periodicity will greatly increase the bandwidth of the problem. A [[Resequence Command]] can be used, but is unlikely to help much. The problem is that periodic conditions causes edge nodes to be related to displacement of nodes on the opposite end for the object. This loss of locality disrupts the resequencing algorithm, which is based on an assumption that nodes depend only on nodes in common elements.
# Because periodicity increases the band width, it should only be used when needed. If the edges of a periodic problem remain planar and parallel, then the periodicity can be achieved with simple displacement boundary conditions. One way to check if this situation holds is to run with true periodic boundary conditions and check the displacements on the edges.

Latest revision as of 13:19, 2 June 2015

NairnFEA can solve problems with truly periodic boundary conditions in one or both directions.

Introduction

Periodic boundary conditions means to run calculations that are periodic in strain in just the x direction, just the y direction, or in both the x and y directions. For axisymmetric problems the calculations can only be periodic in the z direction. Many researchers use symmetry-based displacement conditions for periodic calculations (thinking they are periodic), but that approach cannot handle problems where plane sections do not remain plane even though the structure and strains are periodic. The periodic conditions in NairnFEA are more advanced than simple symmetry conditions and they are essential for some problems such as shear strain applied to a periodic composite material.

Theory

Periodic.jpg

The figure on the right shows a mesh of width Δx and height Δy in which the left and right edges are parallel to the y axis and each node on the left edge corresponds to a node on the right edge at the same y coordinate. If this structure is a piece on a large object that is periodic in the x direction only, it means that the strains are periodic or that:

      [math]\displaystyle{ \varepsilon_{xx}(x+\Delta x,y) = \varepsilon_{xx}(x,y) }[/math]

      [math]\displaystyle{ \varepsilon_{yy}(x+\Delta x,y) = \varepsilon_{yy}(x,y) }[/math]

      [math]\displaystyle{ \gamma_{yx}(x+\Delta x,y) = \gamma_{xy}(x,y) }[/math]

These conditions are satisfied, in the most general sense, if the x and y displacements (u(x,y) and v(x,y)) have the form:

      [math]\displaystyle{ u(x+\Delta x,y) = u(x,y) + k_1 + k_2 y }[/math]

      [math]\displaystyle{ v(x+\Delta x,y) = v(x,y) + k_3 - k_2 x }[/math]

If there are n nodes on each edge, these conditions are satisfied if the problem is solved subjected to the following constraints:

      [math]\displaystyle{ u_i(\Delta x,y_i) = u_i(0,y_i) + k_1 + k_2 y_i \qquad {\rm for}\ i=1,\ {\rm to}\ n }[/math]

      [math]\displaystyle{ v_i(\Delta x,y_i) = v_i(0,y_i) + v_1(\Delta x,y_1) - v_1(0,y_1) \qquad {\rm for}\ i=2,\ {\rm to}\ n }[/math]

These conditions are solved by using FEA method of Lagrange multipliers. All x displacements on the right are replaced by constraints as are all y (except [math]\displaystyle{ v_1(\Delta x,y_1) }[/math], which remains a degree of freedom). In addition, k1 and k2 are introduced as two new degrees of freedom. It is better to rewrite new degrees of freedom using

      [math]\displaystyle{ k_1 + k_2 y_i = \Delta u_n + {\Delta u_s\over \Delta y}(y_i - \left\langle y\right\rangle) }[/math]

where <y> is the mean y on the edges. Physically, Δun is the mean displacement jump in the x direction across the modeled object, which results in an average x direction strain:

      [math]\displaystyle{ \left\langle \varepsilon_{xx}\right\rangle = {\Delta u_n\over \Delta x} }[/math]

Similarly, Δus the shear jump in the x direction or the difference in x direction jumps at the top and bottom of the object. Like nodal displacements, these new terms resulting from periodic boundary conditions can be degrees of freedom (i.e., output of the analysis) or can be inputs (e.g., boundary conditions that impose an average stretch or shear displacement to the edges).

Using the same analysis on problems that are periodic only in the y (or the Z of axisymmetric analysis) direction gives a series of constraints for displacements on the nodes at the top of the object relative to the displacements on the bottom edge. The new constraints lead to two more degrees of freedom - Δvn and Δvs. Physically, Δvn is the mean displacement jump across the modeled object, which results in an average y direction strain:

      [math]\displaystyle{ \left\langle \varepsilon_{yy}\right\rangle = {\Delta v_n\over \Delta y} }[/math]

Similarly, Δvs the shear jump in the y direction or the difference in y direction jumps at the left and right of the object.

If both directions are periodic, the analysis needs some modifications. The general displacement constraints between left and right or top and bottom edges can be written:

      [math]\displaystyle{ u_i(\Delta x,y_i) = u_i(0,y_i) + \left\langle \varepsilon_{xx}\right\rangle \Delta x = u_i(0,y_i) + \Delta u_n }[/math]

      [math]\displaystyle{ v_i(\Delta x,y_i) = v_i(0,y_i) + \left({\left\langle\gamma_{xy}\right\rangle\over 2} - \omega\right) \Delta x = v_i(0,y_i) + \Delta v_s }[/math]

      [math]\displaystyle{ u_i(x_i,\Delta y) = u_i(x_i,0) + \left({\left\langle \gamma_{xy}\right\rangle\over 2} + \omega\right) \Delta y = u_i(x_i,0) + \Delta u_s }[/math]

      [math]\displaystyle{ v_i(x_i,\Delta y) = v_i(x_i,0) + \left\langle \varepsilon_{yy}\right\rangle \Delta y = v_i(x_i,0) + \Delta v_n }[/math]

where ω is a rigid body rotation. The average normal strains are as above. The average shear strain is

      [math]\displaystyle{ \left\langle \gamma_{xy}\right\rangle = {\Delta u_s\over \Delta y} + {\Delta v_s\over \Delta x} }[/math]

For axisymmetric problems, the model cannot be periodic in the R direction. It can be periodic in the Z direction, but to maintain periodicity in the hoop stress (εθθ), the top and bottom edges must not rotate. In other words, the shear stretch (Δvs) must be zero (i.e., it is not a degree of freedom). The average axial strain is related to Δwn or the displacement jump in the vertical direction:

      [math]\displaystyle{ \left\langle \varepsilon_{ZZ}\right\rangle = {\Delta w_n\over \Delta Z} }[/math]

Input Commands

In scripted files, you set up periodic boundary conditions with one or two Periodic commands:

Periodic (dir),<(dof1),(value1)>,<(dof2),(value2)>

In XML, the one or two commands, which must be in the <GridBCs> block, are:

<Periodic dof='(dir)' delta='(value1)' slope='(value2)'/>

where

  • (dir) defines the periodic direction. NairnFEA allows periodicity in the x direction only, in the y direction only, or in both the x and y directions. For axisymmetric problems, periodicity is allowed in the Z direction only.
  • The optional (dof1),(value1) and (dof2),(value2) in scripted files can fix one or two periodic boundary degrees of freedom. In each pair, the dof is the degree or freedom and value is the setting. The options for dof are:
    1. Delta to set the displacement jump in that direction (in length units). When applied to the x direction, the global average strain is <εxx> = Delta/Δx. When applied to the y direction, the global average strain is <εyy> = Delta/Δy. When applied to the Z direction in axisymmetric analyses, the global average strain is <εzz> = Delta/Δz. Here Δx, Δy, and Δz are the specimen lengths in those directions.
    2. Slope defines the relative edge slopes between the two sides when there is one periodic direction (dimensioness). It is Δus/Δy for x direction only and Δvs/Δx for y (or Z) direction only.
    3. Shear defines the shearing displacement jump difference between the two sides of the periodic direction (in length units) when both directions are periodic. It is Δus for x direction setting and Δvs for y (or Z) direction setting. When periodic in both x and y directions, the average shear strain is <γxy> = ShearX/Δy + ShearY/Δx. Here Δx and Δy are the specimen lengths in the two directions, ShearX is Δus, and ShearY is Δvs.
  • In XML files, optional (value1) and (value2) set the displacement jump and rotation using delta and slope, shear attributes.

For periodicity to work, the edges of the specimen on the two ends of the periodic direction(s) must be orthognal to that direction, they must each have the same number of nodes, and the orthogonal coordinate (e.g., the y coordinate for x periodicity, the x coordinate for y periodicity, or the R coordinate for Z periodicity) of each node on one side must match the corresponding node on the other side.

Setting the periodic degrees of freedom for Delta, Slope, and Shear are optional. If they are not set, they are degrees of freedom in the problem (and can be found from output results). If they are set as boundary conditions, they can determine the average normal strains, edge rotations, and average shear strains. Finally, scripted commands can use Slope as a synonym from Shear and XML command can use a slope attribute as a synonym for the shear attribute. The code defines the appropriately condition depending on whether one or two directions are made periodic.

Notes

  1. Adding periodicity will greatly increase the bandwidth of the problem. A Resequence Command can be used, but is unlikely to help much. The problem is that periodic conditions causes edge nodes to be related to displacement of nodes on the opposite end for the object. This loss of locality disrupts the resequencing algorithm, which is based on an assumption that nodes depend only on nodes in common elements.
  2. Because periodicity increases the band width, it should only be used when needed. If the edges of a periodic problem remain planar and parallel, then the periodicity can be achieved with simple displacement boundary conditions. One way to check if this situation holds is to run with true periodic boundary conditions and check the displacements on the edges.