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https://git.salome-platform.org/gitpub/modules/smesh.git
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385 lines
8.5 KiB
Plaintext
385 lines
8.5 KiB
Plaintext
/*!
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\page tui_defining_hypotheses_page Defining Hypotheses and Algorithms
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<h2>Defining 1D Hypotheses</h2>
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<br>
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\anchor tui_1d_arithmetic
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<h3>1D Arithmetic</h3>
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\code
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import geompy
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import smesh
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# create a box
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box = geompy.MakeBoxDXDYDZ(10., 10., 10.)
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geompy.addToStudy(box, "Box")
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# create a hexahedral mesh on the box
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hexa = smesh.Mesh(box, "Box : hexahedrical mesh")
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# create a Regular 1D algorithm for edges
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algo1D = hexa.Segment()
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# define "Arithmetic1D" hypothesis to cut all edges in several segments with increasing arithmetic length
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algo1D.Arithmetic1D(1, 4)
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# create a quadrangle 2D algorithm for faces
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hexa.Quadrangle()
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# create a hexahedron 3D algorithm for solids
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hexa.Hexahedron()
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# compute the mesh
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hexa.Compute()
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\endcode
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<br>
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\anchor tui_deflection_1d
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<h3>Deflection 1D and Number of Segments</h3>
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\code
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import geompy
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import smesh
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# create a face from arc and straight segment
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px = geompy.MakeVertex(100., 0. , 0. )
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py = geompy.MakeVertex(0. , 100., 0. )
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pz = geompy.MakeVertex(0. , 0. , 100.)
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exy = geompy.MakeEdge(px, py)
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arc = geompy.MakeArc(py, pz, px)
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wire = geompy.MakeWire([exy, arc])
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isPlanarFace = 1
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face1 = geompy.MakeFace(wire, isPlanarFace)
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geompy.addToStudy(face1,"Face1")
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# get edges from the face
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e_straight,e_arc = geompy.SubShapeAll(face1, geompy.ShapeType["EDGE"])
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geompy.addToStudyInFather(face1, e_arc, "Arc Edge")
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# create hexahedral mesh
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hexa = smesh.Mesh(face1, "Face : triangle mesh")
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# define "NumberOfSegments" hypothesis to cut a straight edge in a fixed number of segments
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algo1D = hexa.Segment()
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algo1D.NumberOfSegments(6)
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# define "MaxElementArea" hypothesis
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algo2D = hexa.Triangle()
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algo2D.MaxElementArea(70.0)
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# define a local "Deflection1D" hypothesis on the arc
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algo_local = hexa.Segment(e_arc)
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algo_local.Deflection1D(1.0)
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# compute the mesh
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hexa.Compute()
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\endcode
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<br>
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\anchor tui_start_and_end_length
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<h3>Start and End Length</h3>
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\code
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from geompy import *
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import smesh
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# create a box
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box = MakeBoxDXDYDZ(10., 10., 10.)
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addToStudy(box, "Box")
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# get one edge of the box to put local hypothesis on
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p5 = MakeVertex(5., 0., 0.)
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EdgeX = GetEdgeNearPoint(box, p5)
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addToStudyInFather(box, EdgeX, "Edge [0,0,0 - 10,0,0]")
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# create a hexahedral mesh on the box
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hexa = smesh.Mesh(box, "Box : hexahedrical mesh")
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# set algorithms
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algo1D = hexa.Segment()
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hexa.Quadrangle()
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hexa.Hexahedron()
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# define "NumberOfSegments" hypothesis to cut an edge in a fixed number of segments
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algo1D.NumberOfSegments(4)
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# create a local hypothesis
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algo_local = hexa.Segment(EdgeX)
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# define "StartEndLength" hypothesis to cut an edge in several segments with increasing geometric length
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algo_local.StartEndLength(1, 6)
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# define "Propagation" hypothesis that propagates all other hypothesis
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# on all edges on the opposite side in case of quadrangular faces
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algo_local.Propagation()
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# compute the mesh
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hexa.Compute()
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\endcode
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<br>
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\anchor tui_average_length
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<h3>Average Length</h3>
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\code
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from geompy import *
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import smesh
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# create a box
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box = MakeBoxDXDYDZ(10., 10., 10.)
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addToStudy(box, "Box")
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# get one edge of the box to put local hypothesis on
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p5 = MakeVertex(5., 0., 0.)
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EdgeX = GetEdgeNearPoint(box, p5)
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addToStudyInFather(box, EdgeX, "Edge [0,0,0 - 10,0,0]")
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# create a hexahedral mesh on the box
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hexa = smesh.Mesh(box, "Box : hexahedrical mesh")
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# set algorithms
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algo1D = hexa.Segment()
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hexa.Quadrangle()
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hexa.Hexahedron()
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# define "NumberOfSegments" hypothesis to cut all edges in a fixed number of segments
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algo1D.NumberOfSegments(4)
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# create a sub-mesh
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algo_local = hexa.Segment(EdgeX)
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# define "LocalLength" hypothesis to cut an edge in several segments with the same length
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algo_local.LocalLength(2.)
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# define "Propagation" hypothesis that propagates all other hypothesis
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# on all edges on the opposite side in case of quadrangular faces
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algo_local.Propagation()
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# compute the mesh
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hexa.Compute()
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\endcode
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<br><h2>Defining 2D and 3D hypotheses</h2>
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<br>
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\anchor tui_max_element_area
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<h3>Maximum Element Area</h3>
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\code
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import geompy
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import smesh
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import salome
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# create a face
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px = geompy.MakeVertex(100., 0. , 0. )
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py = geompy.MakeVertex(0. , 100., 0. )
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pz = geompy.MakeVertex(0. , 0. , 100.)
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vxy = geompy.MakeVector(px, py)
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arc = geompy.MakeArc(py, pz, px)
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wire = geompy.MakeWire([vxy, arc])
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isPlanarFace = 1
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face = geompy.MakeFace(wire, isPlanarFace)
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# add the face in the study
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id_face = geompy.addToStudy(face, "Face to be meshed")
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# create a mesh
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tria_mesh = smesh.Mesh(face, "Face : triangulation")
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# define 1D meshing:
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algo = tria_mesh.Segment()
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algo.NumberOfSegments(20)
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# define 2D meshing:
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# assign triangulation algorithm
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algo = tria_mesh.Triangle()
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# apply "Max Element Area" hypothesis to each triangle
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algo.MaxElementArea(100)
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# compute the mesh
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tria_mesh.Compute()
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\endcode
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<br>
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\anchor tui_max_element_volume
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<h3>Maximum Element Volume</h3>
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\code
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import geompy
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import smesh
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# create a cylinder
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cyl = geompy.MakeCylinderRH(30., 50.)
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geompy.addToStudy(cyl, "cyl")
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# create a mesh on the cylinder
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tetra = smesh.Mesh(cyl, "Cylinder : tetrahedrical mesh")
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# assign algorithms
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algo1D = tetra.Segment()
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algo2D = tetra.Triangle()
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algo3D = tetra.Tetrahedron(smesh.NETGEN)
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# assign 1D and 2D hypotheses
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algo1D.NumberOfSegments(7)
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algo2D.MaxElementArea(150.)
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# assign Max Element Volume hypothesis
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algo3D.MaxElementVolume(200.)
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# compute the mesh
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ret = tetra.Compute()
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if ret == 0:
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print "probleme when computing the mesh"
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else:
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print "Computation succeded"
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\endcode
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<br>
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\anchor tui_length_from_edges
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<h3>Length from Edges</h3>
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\code
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import geompy
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import smesh
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# create sketchers
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sketcher1 = geompy.MakeSketcher("Sketcher:F 0 0:TT 70 0:TT 70 70:TT 0 70:WW")
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sketcher2 = geompy.MakeSketcher("Sketcher:F 20 20:TT 50 20:TT 50 50:TT 20 50:WW")
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# create a face from two wires
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isPlanarFace = 1
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face1 = geompy.MakeFaces([sketcher1, sketcher2], isPlanarFace)
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geompy.addToStudy(face1, "Face1")
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# create a mesh
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tria = smesh.Mesh(face1, "Face : triangle 2D mesh")
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# Define 1D meshing
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algo1D = tria.Segment()
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algo1D.NumberOfSegments(2)
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# create and assign the algorithm for 2D meshing with triangles
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algo2D = tria.Triangle()
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# create and assign "LengthFromEdges" hypothesis to build triangles based on the length of the edges taken from the wire
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algo2D.LengthFromEdges()
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# compute the mesh
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tria.Compute()
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\endcode
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<br><h2>Defining Additional Hypotheses</h2>
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<br>
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\anchor tui_propagation
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<h3>Propagation</h3>
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\code
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from geompy import *
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import smesh
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# create a box
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box = MakeBoxDXDYDZ(10., 10., 10.)
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addToStudy(box, "Box")
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# get one edge of the box to put local hypothesis on
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p5 = MakeVertex(5., 0., 0.)
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EdgeX = GetEdgeNearPoint(box, p5)
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addToStudyInFather(box, EdgeX, "Edge [0,0,0 - 10,0,0]")
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# create a hexahedral mesh on the box
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hexa = smesh.Mesh(box, "Box : hexahedrical mesh")
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# set global algorithms and hypotheses
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algo1D = hexa.Segment()
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hexa.Quadrangle()
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hexa.Hexahedron()
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algo1D.NumberOfSegments(4)
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# create a sub-mesh with local 1D hypothesis and propagation
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algo_local = hexa.Segment(EdgeX)
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# define "Arithmetic1D" hypothesis to cut an edge in several segments with increasing length
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algo_local.Arithmetic1D(1, 4)
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# define "Propagation" hypothesis that propagates all other 1D hypotheses
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# from all edges on the opposite side of a face in case of quadrangular faces
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algo_local.Propagation()
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# compute the mesh
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hexa.Compute()
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\endcode
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<br>
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\anchor tui_defining_meshing_algos
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<h2>Defining Meshing Algorithms</h2>
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\code
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import geompy
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import smesh
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# create a box
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box = geompy.MakeBoxDXDYDZ(10., 10., 10.)
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geompy.addToStudy(box, "Box")
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# 1. Create a hexahedral mesh on the box
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hexa = smesh.Mesh(box, "Box : hexahedrical mesh")
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# create a Regular 1D algorithm for edges
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algo1D = hexa.Segment()
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# create a quadrangle 2D algorithm for faces
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algo2D = hexa.Quadrangle()
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# create a hexahedron 3D algorithm for solids
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algo3D = hexa.Hexahedron()
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# define hypotheses
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algo1D.Arithmetic1D(1, 4)
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# compute the mesh
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hexa.Compute()
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# 2. Create a tetrahedral mesh on the box
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tetra = smesh.Mesh(box, "Box : tetrahedrical mesh")
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# create a Regular 1D algorithm for edges
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algo1D = tetra.Segment()
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# create a Mefisto 2D algorithm for faces
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algo2D = tetra.Triangle()
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# create a Netgen 3D algorithm for solids
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algo3D = tetra.Tetrahedron(smesh.NETGEN)
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# define hypotheses
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algo1D.Arithmetic1D(1, 4)
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algo2D.LengthFromEdges()
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# compute the mesh
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tetra.Compute()
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# 3. Create a tetrahedral mesh on the box with NETGEN_2D3D algorithm
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tetraN = smesh.Mesh(box, "Box : tetrahedrical mesh by NETGEN_2D3D")
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# create a Netgen_2D3D algorithm for solids
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algo3D = tetraN.Tetrahedron(smesh.FULL_NETGEN)
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# define hypotheses
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n23_params = algo3D.Parameters()
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# compute the mesh
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tetraN.Compute()
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\endcode
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*/ |