mirror of
https://git.salome-platform.org/gitpub/modules/smesh.git
synced 2024-12-27 01:40:33 +05:00
0dbcca5093
- add math to sphinx to generate the formulas - change the icon to deformed hexahedrons - add a test on deformed hexahedrons - update the example use case on the doc to deformed hexahedrons
183 lines
7.2 KiB
Python
183 lines
7.2 KiB
Python
# -*- coding: iso-8859-1 -*-
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# Copyright (C) 2016-2023 CEA/DEN, EDF R&D
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#
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# This library is free software; you can redistribute it and/or
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# modify it under the terms of the GNU Lesser General Public
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# License as published by the Free Software Foundation; either
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# version 2.1 of the License, or (at your option) any later version.
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#
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# This library is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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# Lesser General Public License for more details.
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#
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# You should have received a copy of the GNU Lesser General Public
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# License along with this library; if not, write to the Free Software
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# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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#
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# See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
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#
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# File : SMESH_controls_scaled_jacobian.py
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# Author : Cesar Conopoima
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# Module : SMESH
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#
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import salome
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import math
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salome.salome_init_without_session()
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import GEOM
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import SMESH
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from salome.geom import geomBuilder
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from salome.smesh import smeshBuilder
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def assertWithDelta( refval, testvals, delta ):
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return ( refval <= testvals+delta and refval >= testvals-delta )
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geompy = geomBuilder.New()
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smesh_builder = smeshBuilder.New()
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Box_1 = geompy.MakeBoxDXDYDZ(10, 10, 10)
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geompy.addToStudy( Box_1, 'Box_1' )
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smesh = smeshBuilder.New()
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Mesh_1 = smesh.Mesh(Box_1,'Mesh_1')
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NETGEN_1D_2D_3D = Mesh_1.Tetrahedron(algo=smeshBuilder.NETGEN_1D2D3D)
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Done = Mesh_1.Compute()
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if not Done:
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raise Exception("Error when computing NETGEN_1D2D3D Mesh for quality control test")
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#For tetra elements
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perfect = 1.0
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externals = math.sqrt( 2.0 )/2.0
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notPerfectElements = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_LessThan, perfect - 1e-12 )
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perfectElements = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_EqualTo, perfect )
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externalElements = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_EqualTo, externals )
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notPerfectIds = Mesh_1.GetIdsFromFilter(notPerfectElements)
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perfectIds = Mesh_1.GetIdsFromFilter(perfectElements)
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externalsIds = Mesh_1.GetIdsFromFilter(externalElements)
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assert( len(notPerfectIds) == 4 )
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assert( len(perfectIds) == 1 )
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assert( len(externalsIds) == 4 )
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# Test GetScaledJacobian by elementId
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for id in range(len(perfectIds)):
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assert( assertWithDelta( perfect, Mesh_1.GetScaledJacobian( perfectIds[ id ] ), 1e-12) )
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for id in range(len(externalsIds)):
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assert( assertWithDelta( externals, Mesh_1.GetScaledJacobian( externalsIds[ id ] ), 1e-12) )
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#For hexa elements
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Mesh_2 = smesh.Mesh(Box_1,'Mesh_2')
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Cartesian_3D = Mesh_2.BodyFitted()
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Body_Fitting_Parameters_1 = Cartesian_3D.SetGrid([ [ '5.0' ], [ 0, 1 ]],[ [ '5.0' ], [ 0, 1 ]],[ [ '5.0' ], [ 0, 1 ]],4,0)
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Done = Mesh_2.Compute()
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if not Done:
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raise Exception("Error when computing BodyFitted Mesh for quality control test")
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notPerfectIds = Mesh_2.GetIdsFromFilter(notPerfectElements)
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perfectIds = Mesh_2.GetIdsFromFilter(perfectElements)
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assert( len(notPerfectIds) == 0 )
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assert( len(perfectIds) == 8 )
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# Test GetScaledJacobian by elementId
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for id in range(len(perfectIds)):
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assert( assertWithDelta( perfect, Mesh_2.GetScaledJacobian( perfectIds[ id ] ), 1e-12) )
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#For hexa elements with poor quality
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Mesh_3 = smesh.Mesh(Box_1,'Mesh_3')
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Cartesian_3D = Mesh_3.BodyFitted()
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Body_Fitting_Parameters_1 = Cartesian_3D.SetGrid([ [ '5.0' ], [ 0, 1 ]],[ [ '5.0' ], [ 0, 1 ]],[ [ '5.0' ], [ 0, 1 ]],4,0)
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Body_Fitting_Parameters_1.SetAxesDirs( SMESH.DirStruct( SMESH.PointStruct ( 1, 0, 1 )), SMESH.DirStruct( SMESH.PointStruct ( 0, 1, 0 )), SMESH.DirStruct( SMESH.PointStruct ( 0, 0, 1 )) )
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Done = Mesh_3.Compute()
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if not Done:
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raise Exception("Error when computing BodyFitted Distorted Mesh for quality control test")
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#Polyhedrons return zero scaled jacobian because of lack for a decomposition into simpler forms
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Polys = 0.0
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#Hexahedrons that are distorted by an angle of 45
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# Scaled Jacobian which is a measure of elements distortion
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# will return cos(45) = math.sqrt( 2.0 )/2.0
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distorted = math.sqrt( 2.0 )/2.0
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polysElements = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_EqualTo, Polys )
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distortedElements = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_EqualTo, distorted )
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polysIds = Mesh_3.GetIdsFromFilter(polysElements)
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distortedIds = Mesh_3.GetIdsFromFilter(distortedElements)
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assert( len(polysIds) == 4 )
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assert( len(distortedIds) == 8 )
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# Test GetScaledJacobian by elementId
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for id in range(len(distortedIds)):
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assert( assertWithDelta( distorted, Mesh_3.GetScaledJacobian( distortedIds[ id ] ), 1e-12 ) )
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#Test the pentahedron
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Mesh_4 = smesh.Mesh(Box_1,'Mesh_4')
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Cartesian_3D = Mesh_4.BodyFitted()
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Body_Fitting_Parameters_1 = Cartesian_3D.SetGrid([ [ '4' ], [ 0, 1 ]],[ [ '4' ], [ 0, 1 ]],[ [ '4' ], [ 0, 1 ]],4,0)
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Body_Fitting_Parameters_1.SetAxesDirs( SMESH.DirStruct( SMESH.PointStruct ( 1, 0, 1 )), SMESH.DirStruct( SMESH.PointStruct ( 0, 1, 0 )), SMESH.DirStruct( SMESH.PointStruct ( 0, 0, 1 )) )
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Body_Fitting_Parameters_1.SetSizeThreshold( 4 )
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Body_Fitting_Parameters_1.SetToAddEdges( 0 )
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Body_Fitting_Parameters_1.SetGridSpacing( [ '2' ], [ 0, 1 ], 0 )
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Body_Fitting_Parameters_1.SetGridSpacing( [ '2' ], [ 0, 1 ], 1 )
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Body_Fitting_Parameters_1.SetGridSpacing( [ '2' ], [ 0, 1 ], 2 )
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Done = Mesh_4.Compute()
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if not Done:
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raise Exception("Error when computing BodyFitted Distorted Mesh for quality control test")
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pentahedrons = 0.6
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pentasAndPolys = smesh.GetFilter(SMESH.VOLUME, SMESH.FT_ScaledJacobian, SMESH.FT_LessThan, pentahedrons )
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polysIds = Mesh_4.GetIdsFromFilter(polysElements)
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pentasAndPolysIds = Mesh_4.GetIdsFromFilter(pentasAndPolys)
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assert( len(pentasAndPolysIds) - len(polysIds) == 10 )
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#Test distorded hexahedrons scaled jacobian values
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Mesh_5 = smesh.Mesh(Box_1,'Mesh_5')
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Regular_1D = Mesh_5.Segment()
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Number_of_Segments_1 = Regular_1D.NumberOfSegments(2)
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Quadrangle_2D = Mesh_5.Quadrangle(algo=smeshBuilder.QUADRANGLE)
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Hexa_3D = Mesh_5.Hexahedron(algo=smeshBuilder.Hexa)
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isDone = Mesh_5.Compute()
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if not Done:
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raise Exception("Error when computing hexaedrons Mesh for quality control test")
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#move some nodes to make scaled jacobian lesser than 1
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node_id_1 = Mesh_5.FindNodeClosestTo(0, 0, 10)
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node_id_5 = Mesh_5.FindNodeClosestTo(10, 0, 10)
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node_id_14 = Mesh_5.FindNodeClosestTo(10, 5, 10)
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node_id_13 = Mesh_5.FindNodeClosestTo(10, 0, 5)
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node_id_6 = Mesh_5.FindNodeClosestTo(10, 0, 0)
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Mesh_5.MoveNode( node_id_1, 1, 1, 9 )
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Mesh_5.MoveNode( node_id_5, 9, 1, 9 )
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Mesh_5.MoveNode( node_id_14, 10, 5, 9 )
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Mesh_5.MoveNode( node_id_13, 9, 0, 5 )
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Mesh_5.MoveNode( node_id_6, 8, 0, 0 )
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yellow_element = Mesh_5.FindElementsByPoint(7.5, 2.5, 2.5)[0]
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green_element = Mesh_5.FindElementsByPoint(7.5, 2.5, 7.5)[0]
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blue_element = Mesh_5.FindElementsByPoint(2.5, 2.5, 7.5)[0]
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yellow_SJ = Mesh_5.GetScaledJacobian(yellow_element)
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green_SJ = Mesh_5.GetScaledJacobian(green_element)
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blue_SJ = Mesh_5.GetScaledJacobian(blue_element)
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yellow_SJ_ref = 0.910446300912
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green_SJ_ref = 0.818025491961
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blue_SJ_ref = 0.654728501099
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assert assertWithDelta( yellow_SJ_ref, yellow_SJ, 1e-10 )
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assert assertWithDelta( green_SJ_ref, green_SJ, 1e-10 )
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assert assertWithDelta( blue_SJ_ref, blue_SJ, 1e-10 )
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