Property#

The Property commands are used to create and manage reinforcements and to assign properties to a part. (See also Material commands and Section commands.) The Property commands are methods of a Part object.

Create properties for Part#

class PropertyPart(name: str, dimensionality: SymbolicConstant, type: SymbolicConstant, twist: Union[AbaqusBoolean, bool] = OFF)[source]

class PropertyPart(name: str, objectToCopy: str, scale: float = 1, mirrorPlane: SymbolicConstant = NONE, compressFeatureList: Union[AbaqusBoolean, bool] = OFF, separate: Union[AbaqusBoolean, bool] = OFF)

Public Data Attributes:

Inherited from PartBase

`geometryValidity`	A Boolean specifying the validity of the geometry of the part.
`isOutOfDate`	An Int specifying that feature parameters have been modified but that the part has not been regenerated.
`timeStamp`	A Float specifying when the part was last modified.
`vertices`	A `VertexArray` object specifying all the vertices in the part.
`ignoredVertices`	An `IgnoredVertexArray` object specifying all the ignored vertices in the part.
`edges`	An `EdgeArray` object specifying all the edges in the part.
`ignoredEdges`	An `IgnoredEdgeArray` object specifying all the ignored edges in the part.
`faces`	A `FaceArray` object specifying all the faces in the part.
`cells`	A `CellArray` object specifying all the cells in the part.
`features`	A repository of Feature objects specifying all the features in the part.
`featuresById`	A repository of Feature objects specifying all Feature objects in the part.
`datums`	A repository of Datum objects specifying all the datums in the part.
`elements`	A `MeshElementArray` object specifying all the elements in the part.
`elemFaces`	A repository of MeshFace objects specifying all the element faces in the part.
`elementFaces`	A `MeshFaceArray` object specifying all the unique element faces in the part.
`nodes`	A `MeshNodeArray` object specifying all the nodes in the part.
`retainedNodes`	A `MeshNodeArray` object specifying all the retained nodes in the substructure part.
`sets`	A repository of Set objects specifying for more information, see Set.
`allSets`	A repository of Set objects specifying the contents of the allSets repository is the same as the contents of the sets repository.
`allInternalSets`	A repository of Set objects specifying picked regions.
`surfaces`	A repository of Surface objects specifying for more information, see Surface.
`allSurfaces`	A repository of Surface objects specifying the contents of the allSurfaces repository is the same as the contents of the surfaces repository.
`allInternalSurfaces`	A repository of Surface objects specifying picked regions.
`skins`	A repository of Skin objects specifying the skins created on the part.
`stringers`	A repository of Stringer objects specifying the stringers created on the part.
`referencePoints`	A repository of ReferencePoint objects.
`engineeringFeatures`	An `EngineeringFeature` object.
`sectionAssignments`	A `SectionAssignmentArray` object.
`materialOrientations`	A `MaterialOrientationArray` object.
`compositeLayups`	A repository of CompositeLayup objects.
`elemEdges`	A repository of MeshEdge objects specifying all the element edges in the part.
`elementEdges`	A `MeshEdgeArray` object specifying all the unique element edges in the part.

Inherited from Feature

`name`	A String specifying the repository key.
`id`	An Int specifying the ID of the feature.

Public Methods:

`CompositeLayup`(name[, description, ...])	This method creates a CompositeLayup object.
`SectionAssignment`(region, sectionName[, ...])	This method creates a SectionAssignment object.
`MaterialOrientation`([region, localCsys, ...])	This method creates a MaterialOrientation object.
`assignBeamSectionOrientation`(region, method, n1)	This method assigns a beam section orientation to a region of a part.
`assignMaterialOrientation`(region, localCsys)	This method assigns a material orientation to a region.
`assignRebarOrientation`(region, localCsys[, ...])	This method assigns a rebar reference orientation to a region.
`flipNormal`(regions[, referenceRegion])	This method flips the normals of shell or membrane elements of an orphan mesh or of two-dimensional geometric regions.
`flipTangent`(regions)	This method flips the tangents of beam or truss elements of an orphan mesh or of one-dimensional geometric regions.
`unassignBeamSectionOrientation`(index)	This method deletes a beam section orientation assignment.
`unassignMaterialOrientation`(index)	This method deletes a material orientation assignment.
`unassignRebarOrientation`(index)	This method deletes a rebar orientation assignment.

Inherited from PartBase

`__init__`(args, *kwargs)
`PartFromBooleanCut`(name, instanceToBeCut, ...)	This method creates a Part in the parts repository after subtracting or cutting the geometries of a group of part instances from that of a base part instance.
`PartFromBooleanMerge`(name, instances[, ...])	This method creates a Part in the parts repository after merging two or more part instances.
`PartFromExtrude2DMesh`(name, part, depth, ...)	This method creates a Part object by extruding an existing two-dimensional orphan mesh Part object in the positive Z-direction and places it in the parts repository.
`PartFromGeometryFile`(name, geometryFile, ...)	This method creates a Part object and places it in the parts repository.
`PartFromInstanceMesh`(name[, partInstances, ...])	This method creates a Part object containing the mesh found in the supplied PartInstance objects and places the new Part object in the parts repository.
`PartFromMesh`(name[, copySets])	This method creates a Part object containing the mesh found in the part and places the new Part object in the parts repository.
`PartFromMeshMirror`(name, part, point1, point2)	This method creates a Part object by mirroring an existing orphan mesh Part object about a specified plane and places it in the parts repository.
`PartFromNodesAndElements`(name, ...[, twist])	This method creates a Part object from nodes and elements and places it in the parts repository.
`PartFromOdb`(name, odb[, fileName, instance, ...])	This method creates an orphan mesh Part object by reading an output database.
`PartFromSection3DMeshByPlane`(name, part, ...)	This method creates a Part object by cutting an existing three-dimensional orphan mesh Part object by a plane and places it in the parts repository.
`PartFromSubstructure`(name, substructureFile, ...)	This method creates a substructure Part object by reading a substructure sim file and places it in the parts repository.
`Part2DGeomFrom2DMesh`(name, part, featureAngle)	This method creates a geometric Part object from the outline of an existing two-dimensional orphan mesh Part object and places it in the parts repository.
`setValues`(args, *kwargs)	This method modifies the Part object.
`addGeomToSketch`(sketch)	This method converts a part into a sketch by projecting all of the edges of the part onto the X-Y plane of the sketch.
`assignThickness`(faces[, thickness, ...])	This method assigns thickness data to shell faces.
`backup`()	This method makes a backup copy of the features in the part.
`checkGeometry`([detailed, reportFacetErrors, ...])	This method checks the validity of the geometry of the part and prints a count of all topological entities on the part (faces, edges, vertices, etc.).
`clearGeometryCache`()	This method clears the geometry cache.
`deleteAllFeatures`()	This method deletes all the features in the part.
`deleteFeatures`(featureNames)	This method deletes the given features.
`getAngle`(plane1, plane2, line1, line2[, ...])	This method returns the angle between the specified entities.
`getArea`(faces[, relativeAccuracy])	This method returns the total surface area of a given face or group of faces.
`getAssociatedCADPaths`()	This method returns the paths to the associated CAD part and root file.
`getCADParameters`()	This method returns the names and values of the CAD parameters associated with the part.
`getCentroid`(faces, cells[, relativeAccuracy])	Location of the centroid of a given face/cell or group of faces/cells
`getCoordinates`(entity, csys)	This method returns the coordinates of specified point.
`getCurvature`(edges[, samplePoints])	This method returns the maximum curvature of a given edge or group of edges.
`getDistance`(entity1, entity2)	Depending on the arguments provided, this method returns one of the following:
`getLength`(edges)	This method returns the length of a given edge or group of edges.
`getPerimeter`(faces)	This method returns the total perimeter of a given face or group of faces.
`getVolume`(cells[, relativeAccuracy])	This method returns the volume area of a given cell or group of cells.
`getMassProperties`([regions, ...])	This method returns the mass properties of a part or region.
`getFeatureFaces`(name)	This method returns a sequence of Face objects that are created by the given feature.
`getFeatureEdges`(name)	This method returns a sequence of Edge objects that are created by the given feature.
`getFeatureCells`(name)	This method returns a sequence of Cell objects that are created by the given feature.
`getFeatureVertices`(name)	This method returns a sequence of ConstrainedSketchVertex objects that are created by the given feature.
`isAlignedWithSketch`()	This method checks if the normal of an analytical rigid surface part is aligned with that of its sketch.
`printAssignedSections`()	This method prints information on each section that has been assigned to a region of the part.
`projectEdgesOntoSketch`(sketch, edges[, ...])	This method projects the selected edges of a part onto the specified ConstrainedSketch object.
`projectReferencesOntoSketch`(sketch[, ...])	This method projects the vertices of specified edges, and datum points from the part onto the specified ConstrainedSketch object.
`queryAttributes`([printResults])	This method prints the following information about a part:
`queryCachedStates`()	This method displays the position of geometric states relative to the sequence of features in the part cache.
`queryGeometry`([relativeAccuracy, printResults])	This method prints the following information about a part:
`queryRegionsMissingSections`()	This method returns all regions in the part that do not have a section assignment but require one for analysis.
`queryDisjointPlyRegions`()	This method provides a list of all composite plys in the current part which have disjoint regions.
`regenerate`()	This method regenerates a part.
`regenerationWarnings`()	This method prints any regeneration warnings associated with the features.
`removeInvalidGeometry`()	Removes all invalid entities from the part, leaving a valid part.
`restore`()	This method restores the parameters of all features in the assembly to the value they had before a failed regeneration.
`resumeAllFeatures`()	This method resumes all the suppressed features in the part.
`resumeFeatures`(featureNames)	This method resumes the specified suppressed features in the part.
`resumeLastSetFeatures`()	This method resumes the last set of features to be suppressed in the part.
`saveGeometryCache`()	This method caches the current geometry.
`setAssociatedCADPaths`([partFile, rootFile])	This method sets the paths to the associated CAD part and root file.
`suppressFeatures`(featureNames)	This method suppresses the given features.
`writeAcisFile`(fileName[, version])	This method exports the geometry of the part to a named file in ACIS format.
`writeCADParameters`(paramFile[, ...])	This method writes the parameters that were imported from the CAD system to a parameter file.
`writeIgesFile`(fileName, flavor)	This method exports the geometry of the part to a named file in IGES format.
`writeStepFile`(fileName)	This method exports the geometry of the part to a named file in STEP format.
`writeVdaFile`(fileName)	This method exports the geometry of the part to a named file in VDA-FS format.
`copyMeshPattern`(elements, faces, elemFaces, ...)	This method copies a mesh pattern from a source region consisting of a set of shell elements or element faces onto a target face, mapping nodes and elements in a one-one correspondence between source and target.
`smoothNodes`(nodes)	This method smooths the given nodes of a native mesh, moving them locally to a more optimal location that improves the quality of the mesh
`Lock`()	This method locks the part.
`Unlock`()	This method unlocks the part.
`LockForUpgrade`()	This method locks the part for upgrade.

Inherited from PartFeature

`AutoRepair`()	This method carries out a sequence of geometry repair operations if it contains invalid entities.
`AddCells`(faceList[, flipped])	This method tries to convert a shell entity to a solid entity.
`AnalyticRigidSurf2DPlanar`(sketch)	This method creates a first Feature object for an analytical rigid surface by creating a planar wire from the given ConstrainedSketch object.
`AnalyticRigidSurfExtrude`(sketch[, depth])	This method creates a first Feature object for an analytical rigid surface by extruding the given ConstrainedSketch object by the given depth, creating a surface.
`AnalyticRigidSurfRevolve`(sketch)	This method creates a first Feature object for an analytical rigid surface by revolving the given ConstrainedSketch object by 360° about the Y-axis.
`AssignMidsurfaceRegion`(cellList)	This method assign a mid-surface property to sequence of Cell objects.
`BaseSolidExtrude`(sketch, depth[, ...])	This method creates a first Feature object by extruding the given ConstrainedSketch object by the given depth, creating a solid.
`BaseSolidRevolve`(sketch, angle[, pitch, ...])	This method creates a first Feature object by revolving the given ConstrainedSketch object by the given angle, creating a solid.
`BaseSolidSweep`(sketch, path)	This method creates a first Feature object by sweeping the given profile ConstrainedSketch object along the path defined by the path ConstrainedSketch object, creating a solid.
`BaseShell`(sketch)	This method creates a first Feature object by creating a planar shell from the given ConstrainedSketch object.
`BaseShellExtrude`(sketch, depth[, ...])	This method creates a first Feature object by extruding the given ConstrainedSketch object by the given depth, creating a shell.
`BaseShellRevolve`(sketch, angle[, pitch, ...])	This method creates a first Feature object by revolving the given ConstrainedSketch object by the given angle, creating a shell.
`BaseShellSweep`(sketch, path)	This method creates a first Feature object by sweeping the given section ConstrainedSketch object along the path defined by the path ConstrainedSketch object, creating a shell.
`BaseWire`(sketch)	This method creates a first Feature object by creating a planar wire from the given ConstrainedSketch object.
`BlendFaces`(side1, side2[, method, path])	This method creates a Feature object by creating new faces that blends two sets of faces.
`Chamfer`(length, edgeList)	This method creates an additional Feature object by chamfering the given list of edges with a given length.
`Mirror`(mirrorPlane, keepOriginal[, ...])	This method mirrors existing part geometry across a plane to create new geometry.
`ConvertToAnalytical`()	This method attempts to change entities into a simpler form that will speed up processing and make entities available during feature operations.
`ConvertToPrecise`([method])	This method attempts to change imprecise entities so that the geometry becomes precise.
`CoverEdges`(edgeList[, tryAnalytical])	This method generates a face using the given edges as the face's boundaries.
`Cut`(sketchPlane, sketchPlaneSide, ...[, ...])	This method creates an additional Feature object by cutting a hole using the given ConstrainedSketch object.
`CutExtrude`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by extruding the given ConstrainedSketch object by the given depth and cutting away material in the solid and shell regions of the part.
`CutLoft`(loftsections[, startCondition, ...])	This method creates an additional Feature object by lofting between the given sections and cutting away material from the part.
`CutRevolve`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by revolving the given ConstrainedSketch object by the given angle and cutting away material from the part.
`CutSweep`(path, profile[, pathPlane, ...])	This method creates an additional Feature object by sweeping the given ConstrainedSketch object along a path which may be a ConstrainedSketch or a sequence of Edge objects and cutting away material from the part.
`ExtendFaces`([faces, extendAlong, distance, ...])	This method extends faces along its free edges by offsetting the external edges along the surfaces.
`FaceFromElementFaces`(elementFaces[, stitch, ...])	This method creates a geometry face from a collection of orphan element faces.
`HoleBlindFromEdges`(plane, planeSide, ...)	This method creates an additional Feature object by creating a circular blind hole of the given diameter and depth and cutting away material in the solid and shell regions of the part.
`HoleFromEdges`(diameter, edge1, distance1, ...)	This method creates an additional Feature object by creating a circular hole of the given diameter in a 2D planar part and cutting away material in the shell and wire regions of the part.
`HoleThruAllFromEdges`(plane, planeSide, ...)	This method creates an additional Feature object by creating a circular through hole of the given diameter and cutting away material in the solid and shell regions of the part.
`MergeEdges`([edgeList, extendSelection])	This method merges edges either by extending the user selection or using only the selected edges.
`OffsetFaces`(faceList[, distance, ...])	This method creates new faces by offsetting existing faces.
`RemoveCells`(cellList)	This method converts a solid entity to a shell entity.
`RemoveFaces`(faceList[, deleteCells])	This method removes faces from a solid entity or from a shell entity.
`RemoveFacesAndStitch`(faceList)	This method removes faces from a solid entity and attempts to close the resulting gap by extending the neighboring faces of the solid.
`RemoveRedundantEntities`([vertexList, ...])	This method removes redundant edges and vertices from a solid or a shell entity.
`RepairFaceNormals`([faceList])	This method works on the entire part or a sequence of shell faces.
`RepairInvalidEdges`(edgeList)	This method repairs invalid edges.
`RepairSliver`(face, point1, point2[, ...])	This method repairs the selected sliver from the selected face.
`RepairSmallEdges`(edgeList[, toleranceChecks])	This method repairs small edges.
`RepairSmallFaces`(faceList[, toleranceChecks])	This method repairs small faces.
`ReplaceFaces`(faceList[, stitch])	This method replaces the selected faces with a single face.
`Round`(radius, edgeList, vertexList)	This method creates an additional Feature object by rounding (filleting) the given list of entities with the given radius.
`Shell`(sketchPlane, sketchPlaneSide, ...[, ...])	This method creates an additional Feature object by creating a planar shell from the given ConstrainedSketch object.
`ShellExtrude`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by extruding the given ConstrainedSketch object by the given depth, creating a shell protrusion.
`ShellLoft`(loftsections[, startCondition, ...])	This method creates an additional Feature object by lofting between the given sections and adding shell faces to the part.
`ShellRevolve`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by revolving the given ConstrainedSketch object by the given angle, creating a shell protrusion.
`ShellSweep`(path, profile[, pathPlane, ...])	This method creates an additional Feature object by sweeping the given ConstrainedSketch object or a sequence of Edge objects along a path which may be a ConstrainedSketch or a sequence of Edge objects, creating a shell swept protrusion.
`SolidExtrude`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by extruding the given ConstrainedSketch object by the given depth, creating a solid protrusion.
`SolidLoft`(loftsections[, startCondition, ...])	This method creates an additional Feature object by lofting between the given sections and adding material to the part.
`SolidRevolve`(sketchPlane, sketchPlaneSide, ...)	This method creates an additional Feature object by revolving the given ConstrainedSketch object by the given angle, creating a solid protrusion.
`SolidSweep`(path, profile[, pathPlane, ...])	This method creates an additional Feature object by sweeping the given ConstrainedSketch object or a Face object along a path which may be a ConstrainedSketch or a sequence of Edge objects, creating a solid swept protrusion.
`Stitch`([edgeList, stitchTolerance])	This method attempts to create a valid part by binding together free and imprecise edges of all the faces of a part.
`Wire`(sketchPlane, sketchPlaneSide, ...[, ...])	This method creates an additional Feature object by creating a planar wire from the given ConstrainedSketch object.
`WireSpline`(points[, mergeType, ...])	This method creates an additional Feature object by creating a spline wire that passes through a sequence of given points.
`WirePolyLine`(points[, mergeType, meshable])	This method creates an additional Feature object by creating a polyline wire that passes through a sequence of given points.
`WireFromEdge`(edgeList)	This method creates an additional Feature object by creating a Wire by selecting one or more Edge objects of a Solid or Shell part.

Inherited from Feature

`AttachmentPoints`(name, points[, ...])	This method creates an attachment points Feature.
`AttachmentPointsAlongDirection`(name, ...[, ...])	This method creates a Feature object by creating attachment points along a direction or between two points.
`AttachmentPointsOffsetFromEdges`(name, edges)	This method creates a Feature object by creating attachment points along or offset from one or more connected edges.
`DatumAxisByCylFace`(face)	This method creates a Feature object and a DatumAxis object along the axis of a cylinder or cone.
`DatumAxisByNormalToPlane`(plane, point)	This method creates a Feature object and a DatumAxis object normal to the specified plane and passing through the specified point.
`DatumAxisByParToEdge`(edge, point)	This method creates a Feature object and a DatumAxis object parallel to the specified edge and passing through the specified point.
`DatumAxisByPrincipalAxis`(principalAxis)	This method creates a Feature object and a DatumAxis object along one of the three principal axes.
`DatumAxisByRotation`(args, *kwargs)
`DatumAxisByThreePoint`(point1, point2, point3)	This method creates a Feature object and a DatumAxis object normal to the circle described by three points and through its center.
`DatumAxisByThruEdge`(edge)	This method creates a Feature object and a DatumAxis object along the specified edge.
`DatumAxisByTwoPlane`(plane1, plane2)	This method creates a Feature object and a DatumAxis object at the intersection of two planes.
`DatumAxisByTwoPoint`(point1, point2)	This method creates a Feature object and a DatumAxis object along the line joining two points.
`DatumCsysByDefault`(coordSysType[, name])	This method creates a Feature object and a DatumCsys object from the specified default coordinate system at the origin.
`DatumCsysByOffset`(coordSysType, ...[, name])	This method creates a Feature object and a DatumCsys object by offsetting the origin of an existing datum coordinate system to a specified point.
`DatumCsysByThreePoints`(coordSysType, origin, ...)	This method creates a Feature object and a DatumCsys object from three points.
`DatumCsysByTwoLines`(coordSysType, line1, line2)	This method creates a Feature object and a DatumCsys object from two orthogonal lines.
`DatumPlaneByPrincipalPlane`(principalPlane, ...)	This method creates a Feature object and a DatumPlane object through the origin along one of the three principal planes.
`DatumPlaneByOffset`(args, *kwargs)
`DatumPlaneByRotation`(plane, axis, angle)	This method creates a Feature object and a DatumPlane object by rotating a plane about the specified axis through the specified angle.
`DatumPlaneByThreePoints`(point1, point2, point3)	This method creates a Feature object and a DatumPlane object defined by passing through three points.
`DatumPlaneByLinePoint`(line, point)	This method creates a Feature object and a DatumPlane object that pass through the specified line and through the specified point that does not lie on the line.
`DatumPlaneByPointNormal`(point, normal)	This method creates a Feature object and a DatumPlane object normal to the specified line and running through the specified point.
`DatumPlaneByTwoPoint`(point1, point2)	This method creates a Feature object and a DatumPlane object midway between two points and normal to the line connecting the points.
`DatumPointByCoordinate`(coords)	This method creates a Feature object and a DatumPoint object at the point defined by the specified coordinates.
`DatumPointByOffset`(point, vector)	This method creates a Feature object and a DatumPoint object offset from an existing point by a vector.
`DatumPointByMidPoint`(point1, point2)	This method creates a Feature object and a DatumPoint object midway between two points.
`DatumPointByOnFace`(face, edge1, offset1, ...)	This method creates a Feature object and a DatumPoint object on the specified face, offset from two edges.
`DatumPointByEdgeParam`(edge, parameter)	This method creates a Feature object and a DatumPoint object along an edge at a selected distance from one end of the edge.
`DatumPointByProjOnEdge`(point, edge)	This method creates a Feature object and a DatumPoint object along an edge by projecting an existing point along the normal to the edge.
`DatumPointByProjOnFace`(point, face)	This method creates a Feature object and a DatumPoint object on a specified face by projecting an existing point onto the face.
`MakeSketchTransform`(sketchPlane[, origin, ...])	This method creates a Transform object.
`PartitionCellByDatumPlane`(cells, datumPlane)	This method partitions one or more cells using the given datum plane.
`PartitionCellByExtendFace`(cells, extendFace)	This method partitions one or more cells by extending the underlying geometry of a given face to partition the target cells.
`PartitionCellByExtrudeEdge`(cells, edges, ...)	This method partitions one or more cells by extruding selected edges in the given direction.
`PartitionCellByPatchNCorners`(cell, cornerPoints)	This method partitions a cell using an N-sided cutting patch defined by the given corner points.
`PartitionCellByPatchNEdges`(cell, edges)	This method partitions a cell using an N-sided cutting patch defined by the given edges.
`PartitionCellByPlaneNormalToEdge`(cells, ...)	This method partitions one or more cells using a plane normal to an edge at the given edge point.
`PartitionCellByPlanePointNormal`(cells, ...)	This method partitions one or more cells using a plane defined by a point and a normal direction.
`PartitionCellByPlaneThreePoints`(cells, ...)	This method partitions one or more cells using a plane defined by three points.
`PartitionCellBySweepEdge`(cells, edges, sweepPath)	This method partitions one or more cells by sweeping selected edges along the given sweep path.
`PartitionEdgeByDatumPlane`(edges, datumPlane)	This method partitions an edge where it intersects with a datum plane.
`PartitionEdgeByParam`(edges, parameter)	This method partitions one or more edges at the given normalized edge parameter.
`PartitionEdgeByPoint`(edge, point)	This method partitions an edge at the given point.
`PartitionFaceByAuto`(face)	This method automatically partitions a target face into simple regions that can be meshed using a structured meshing technique.
`PartitionFaceByCurvedPathEdgeParams`(face, ...)	This method partitions a face normal to two edges, using a curved path between the two given edge points defined by the normalized edge parameters.
`PartitionFaceByCurvedPathEdgePoints`(face, ...)	This method partitions a face normal to two edges, using a curved path between the two given edge points.
`PartitionFaceByDatumPlane`(faces, datumPlane)	This method partitions one or more faces using the given datum plane.
`PartitionFaceByExtendFace`(faces, extendFace)	This method partitions one or more faces by extending the underlying geometry of another given face to partition the target faces.
`PartitionFaceByIntersectFace`(faces, cuttingFaces)	This method partitions one or more faces using the given cutting faces to partition the target faces.
`PartitionFaceByProjectingEdges`(faces, edges)	This method partitions one or more faces by projecting the given edges on the target faces.
`PartitionFaceByShortestPath`(faces, point1, ...)	This method partitions one or more faces using a minimum distance path between the two given points.
`PartitionFaceBySketch`(faces, sketch[, ...])	This method partitions one or more planar faces by sketching on them.
`PartitionFaceBySketchDistance`(faces, ...[, ...])	This method partitions one or more faces by sketching on a sketch plane and then projecting the sketch toward the target faces through the given distance.
`PartitionFaceBySketchRefPoint`(faces, ...[, ...])	This method partitions one or more faces by sketching on a sketch plane and then projecting the sketch toward the target faces through a distance governed by the reference point.
`PartitionFaceBySketchThruAll`(faces, ...[, ...])	This method partitions one or more faces by sketching on a sketch plane and then projecting toward the target faces through an infinite distance.
`ReferencePoint`(point[, instanceName])	This method creates a Feature object and a ReferencePoint object at the specified location.
`RemoveWireEdges`(wireEdgeList)	This method removes wire edges.
`WirePolyLine`(points[, mergeType, meshable])	This method creates an additional Feature object by creating a polyline wire that passes through a sequence of given points.
`isSuppressed`()	This method queries the suppressed state of the feature.
`restore`()	This method restores the parameters of all features in the assembly to the value they had before a failed regeneration.
`resume`()	This method resumes suppressed features.
`setValues`(args, *kwargs)	This method modifies the Part object.
`suppress`()	This method suppresses features.