EBSDMesh

Mesh generated from a specified DREAM.3D EBSD data file.

The mesh is generated from the EBSD information, to get an optimal reconstruction of the data. This is accomplished in the mesh block using the EBSDMesh type. The same data file used with the EBSD reader is used in the EBSDReader UserObject. The mesh is created with one node per data point in the EBSD data file. If you wish to use mesh adaptivity and allow the mesh to get coarser during the simulation, the "uniform_refine" parameter is used to set how many times the mesh can be coarsened. For this to work the number of elements along _each_ dimension has to be divisible by where is the value of the uniform_refine parameter.

warning:"uniform_refine" parameter

Contrary to other mesh objects the "uniform_refine" parameter will not affect the resolution of the final mesh. It sets the levels of coarsening that can be applied to the EBSD data.

Input Parameters

  • filenameThe name of the file containing the EBSD data

    C++ Type:FileName

    Description:The name of the file containing the EBSD data

Required Parameters

  • elem_typeThe type of element from libMesh to generate (default: linear element for requested dimension)

    C++ Type:MooseEnum

    Description:The type of element from libMesh to generate (default: linear element for requested dimension)

  • uniform_refine0Number of coarsening levels available in adaptive mesh refinement.

    Default:0

    C++ Type:unsigned int

    Description:Number of coarsening levels available in adaptive mesh refinement.

  • ghosting_patch_sizeThe number of nearest neighbors considered for ghosting purposes when 'iteration' patch update strategy is used. Default is 5 * patch_size.

    C++ Type:unsigned int

    Description:The number of nearest neighbors considered for ghosting purposes when 'iteration' patch update strategy is used. Default is 5 * patch_size.

  • gauss_lobatto_gridFalseGrade mesh into boundaries according to Gauss-Lobatto quadrature spacing.

    Default:False

    C++ Type:bool

    Description:Grade mesh into boundaries according to Gauss-Lobatto quadrature spacing.

  • bias_x1The amount by which to grow (or shrink) the cells in the x-direction.

    Default:1

    C++ Type:double

    Description:The amount by which to grow (or shrink) the cells in the x-direction.

  • bias_y1The amount by which to grow (or shrink) the cells in the y-direction.

    Default:1

    C++ Type:double

    Description:The amount by which to grow (or shrink) the cells in the y-direction.

  • bias_z1The amount by which to grow (or shrink) the cells in the z-direction.

    Default:1

    C++ Type:double

    Description:The amount by which to grow (or shrink) the cells in the z-direction.

  • parallel_typeDEFAULTDISTRIBUTED: Always use libMesh::DistributedMesh REPLICATED: Always use libMesh::ReplicatedMesh DEFAULT: Use libMesh::ReplicatedMesh unless --distributed-mesh is specified on the command line

    Default:DEFAULT

    C++ Type:MooseEnum

    Description:DISTRIBUTED: Always use libMesh::DistributedMesh REPLICATED: Always use libMesh::ReplicatedMesh DEFAULT: Use libMesh::ReplicatedMesh unless --distributed-mesh is specified on the command line

  • allow_renumberingTrueIf allow_renumbering=false, node and element numbers are kept fixed until deletion

    Default:True

    C++ Type:bool

    Description:If allow_renumbering=false, node and element numbers are kept fixed until deletion

  • max_leaf_size10The maximum number of points in each leaf of the KDTree used in the nearest neighbor search. As the leaf size becomes larger,KDTree construction becomes faster but the nearest neighbor searchbecomes slower.

    Default:10

    C++ Type:unsigned int

    Description:The maximum number of points in each leaf of the KDTree used in the nearest neighbor search. As the leaf size becomes larger,KDTree construction becomes faster but the nearest neighbor searchbecomes slower.

Optional Parameters

  • partitionerdefaultSpecifies a mesh partitioner to use when splitting the mesh for a parallel computation.

    Default:default

    C++ Type:MooseEnum

    Description:Specifies a mesh partitioner to use when splitting the mesh for a parallel computation.

  • centroid_partitioner_directionSpecifies the sort direction if using the centroid partitioner. Available options: x, y, z, radial

    C++ Type:MooseEnum

    Description:Specifies the sort direction if using the centroid partitioner. Available options: x, y, z, radial

Partitioning Parameters

  • enableTrueSet the enabled status of the MooseObject.

    Default:True

    C++ Type:bool

    Description:Set the enabled status of the MooseObject.

  • patch_update_strategyneverHow often to update the geometric search 'patch'. The default is to never update it (which is the most efficient but could be a problem with lots of relative motion). 'always' will update the patch for all slave nodes at the beginning of every timestep which might be time consuming. 'auto' will attempt to determine at the start of which timesteps the patch for all slave nodes needs to be updated automatically.'iteration' updates the patch at every nonlinear iteration for a subset of slave nodes for which penetration is not detected. If there can be substantial relative motion between the master and slave surfaces during the nonlinear iterations within a timestep, it is advisable to use 'iteration' option to ensure accurate contact detection.

    Default:never

    C++ Type:MooseEnum

    Description:How often to update the geometric search 'patch'. The default is to never update it (which is the most efficient but could be a problem with lots of relative motion). 'always' will update the patch for all slave nodes at the beginning of every timestep which might be time consuming. 'auto' will attempt to determine at the start of which timesteps the patch for all slave nodes needs to be updated automatically.'iteration' updates the patch at every nonlinear iteration for a subset of slave nodes for which penetration is not detected. If there can be substantial relative motion between the master and slave surfaces during the nonlinear iterations within a timestep, it is advisable to use 'iteration' option to ensure accurate contact detection.

  • control_tagsAdds user-defined labels for accessing object parameters via control logic.

    C++ Type:std::vector

    Description:Adds user-defined labels for accessing object parameters via control logic.

  • nemesisFalseIf nemesis=true and file=foo.e, actually reads foo.e.N.0, foo.e.N.1, ... foo.e.N.N-1, where N = # CPUs, with NemesisIO.

    Default:False

    C++ Type:bool

    Description:If nemesis=true and file=foo.e, actually reads foo.e.N.0, foo.e.N.1, ... foo.e.N.N-1, where N = # CPUs, with NemesisIO.

  • construct_node_list_from_side_listTrueWhether or not to generate nodesets from the sidesets (usually a good idea).

    Default:True

    C++ Type:bool

    Description:Whether or not to generate nodesets from the sidesets (usually a good idea).

  • patch_size40The number of nodes to consider in the NearestNode neighborhood.

    Default:40

    C++ Type:unsigned int

    Description:The number of nodes to consider in the NearestNode neighborhood.

Advanced Parameters