def __init__(self, point_coords, element_nodes, spring_constant=1.): self.pts = array(point_coords, copy=1) self.elnodes = array(element_nodes, copy=1) self.npts = len(self.pts) self.nels = len(self.elnodes) self.mesh = gf.Mesh('empty', 2) for i in range(self.npts): self.mesh.add_point(self.pts[i, :]) for i in range(self.nels): self.mesh.add_convex(gf.GeoTrans('GT_PK(1,1)'), transpose(self.pts[self.elnodes[i, :]])) self.fem = gf.MeshFem(self.mesh) self.ptdm = zeros( (self.npts, 2), dtype=int ) # point-to-dof-map i.e. rhs=self.model.rhs() then rhs[ptdm[p,i]] applies to point p and coordinate axis i self.fem.set_qdim(2) self.fem.set_classical_fem(1) # classic means Lagrange polynomial self.mim = gf.MeshIm(self.mesh, gf.Integ('IM_GAUSS1D(2)')) self.model = gf.Model('real') # 2D model variable U is of real value self.EA = spring_constant # stiffness k = E*A self.model.add_initialized_data( 'lambda', self.EA) # define Lame coefficients lambda and mu self.model.add_initialized_data('mu', 0) # define Lame coefficients lambda and mu self.model.add_fem_variable('U', self.fem) self.model.add_isotropic_linearized_elasticity_brick( self.mim, 'U', 'lambda', 'mu') self.nreg = 0 # how many regions are defined on the mesh self.fixreg = 0 # how many regions have been created for the purpose of fixing nodes self.loadreg = 0 # how many regions have been created for the purpose of loading nodes self.s_pts = zeros((self.npts, 2)) # shifted points self.lengths = zeros(self.nels) # element lengths self.s_lengths = zeros( self.nels) # element lengths in deformed geometry self.elong = zeros(self.nels) # element elongation factor self.p_elong = zeros(self.nels) # element percentage of elongation self.delta_l = zeros(self.nels) # element length differences self.thescore = 0
generally GetFEM are working. It focuses on testing some operations of the high generic assembly language. $Id$ """ import numpy as np import getfem as gf import os NX = 4 m1 = gf.Mesh('cartesian', np.arange(0, 1 + 1. / NX, 1. / NX)) # Structured 1D mesh mfu1 = gf.MeshFem(m1, 1) mfu1.set_fem(gf.Fem('FEM_PK(1,1)')) mim1 = gf.MeshIm(m1, gf.Integ('IM_GAUSS1D(4)')) U1 = mfu1.eval('x') m2 = gf.Mesh('triangles grid', np.arange(0, 1 + 1. / NX, 1. / NX), np.arange(0, 1 + 1. / NX, 1. / NX)) # Structured 2D mesh mfu2 = gf.MeshFem(m2, 1) mfu2.set_fem(gf.Fem('FEM_PK(2,1)')) mim2 = gf.MeshIm(m2, gf.Integ('IM_TRIANGLE(4)')) U2 = mfu2.eval('x+y') md = gf.Model('real') md.add_fem_variable('u1', mfu1) md.set_variable('u1', U1) md.add_fem_variable('u2', mfu2) md.set_variable('u2', U2)
# lawname = 'Ciarlet Geymonat' # params = [1.,1.,0.25] lawname = 'SaintVenant Kirchhoff' params = [1.,1.] if (incompressible): lawname = 'Incompressible Mooney Rivlin' params = [1.,1.] N1 = 2; N2 = 4; h = 20.; DX = 1./N1; DY = (1.*h)/N2; m = gf.Mesh('cartesian', np.arange(-0.5, 0.5+DX,DX), np.arange(0., h+DY,DY), np.arange(-1.5, 1.5+3*DX,3*DX)) mfu = gf.MeshFem(m, 3) # mesh-fem supporting a 3D-vector field mfdu = gf.MeshFem(m,1) # The mesh_im stores the integration methods for each tetrahedron mim = gf.MeshIm(m, gf.Integ('IM_GAUSS_PARALLELEPIPED(3,4)')) # We choose a P2 fem for the main unknown mfu.set_fem(gf.Fem('FEM_QK(3,2)')) if (dirichlet_version == 1): mfd = mfu; else: mfd = gf.MeshFem(m,1) mfd.set_fem(gf.Fem('FEM_QK(3,1)')) # The P2 fem is not derivable across elements, hence we use a discontinuous # fem for the derivative of U. mfdu.set_fem(gf.Fem('FEM_QK_DISCONTINUOUS(3,2)')); # Display some information about the mesh print('nbcvs=%d, nbpts=%d, nbdof=%d' % (m.nbcvs(), m.nbpts(), mfu.nbdof()))
# coding: utf-8 import getfem as gf import numpy as np m = gf.Mesh('cartesian', np.arange(0.0, 10.0, 1.0)) print m mfu = gf.MeshFem(m,1) mfu.set_fem(gf.Fem('FEM_PK(1,1)')) mim = gf.MeshIm(m, gf.Integ('IM_GAUSS1D(1)')) mfd = gf.MeshFem(m, 1) mfd.set_fem(gf.Fem('FEM_PK(1,1)')) nbd = mfd.nbdof() Lambda = 1.0; Mu = 1.0 K = gf.asm_linear_elasticity(mim, mfu, mfd, np.repeat([Lambda], nbd), np.repeat([Mu], nbd)) K.full() print 'Lambda = ', Lambda print 'Mu = ', Mu print K.full() print '2*Mu+Lambda = ', 2*Mu+Lambda
mfu.set_fem( gf.Fem('FEM_HHO(FEM_SIMPLEX_IPK(%d,2),FEM_SIMPLEX_CIPK(%d,2))' % (N, N - 1))) mfur.set_fem(gf.Fem('FEM_PK(%d,3)' % N)) else: mfu.set_fem(gf.Fem('FEM_PK(%d,2)' % N)) mfur.set_fem(gf.Fem('FEM_PK(%d,2)' % N)) mfgu.set_fem(gf.Fem('FEM_PK(%d,2)' % N)) mfrhs.set_fem(gf.Fem('FEM_PK(%d,2)' % N)) print('nbdof : %d' % mfu.nbdof()) # Integration method used if (N == 2): mim = gf.MeshIm(m, gf.Integ('IM_TRIANGLE(4)')) else: mim = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) # Boundary selection flst = m.outer_faces() fnor = m.normal_of_faces(flst) tleft = abs(fnor[1, :] + 1) < 1e-14 ttop = abs(fnor[0, :] - 1) < 1e-14 fleft = np.compress(tleft, flst, axis=1) ftop = np.compress(ttop, flst, axis=1) fneum = np.compress(np.logical_not(ttop + tleft), flst, axis=1) # Mark it as boundary DIRICHLET_BOUNDARY_NUM1 = 1 DIRICHLET_BOUNDARY_NUM2 = 2
mfu.set_fem(gf.Fem('FEM_PK(2,2)')) mfur.set_fem(gf.Fem('FEM_PK(2,2)')) if (use_quad): mfgu.set_fem(gf.Fem('FEM_QUAD_IPK(2,2)')) # mfgu.set_fem(gf.Fem('FEM_QK(2,2)')) mfrhs.set_fem(gf.Fem('FEM_QK(2,3)')) else: mfgu.set_fem(gf.Fem('FEM_PK(2,2)')) mfrhs.set_fem(gf.Fem('FEM_PK(2,3)')) print('nbdof : %d' % mfu.nbdof()); # Integration method used if (use_quad): mim = gf.MeshIm(m, gf.Integ('IM_GAUSS_PARALLELEPIPED(2,6)')) else: mim = gf.MeshIm(m, gf.Integ('IM_TRIANGLE(6)')) # Boundary selection flst = m.outer_faces() GAMMAD = 1 m.set_region(GAMMAD, flst) # Faces for stabilization term all_faces = m.all_faces() ALL_FACES = 4 m.set_region(ALL_FACES, all_faces) # Interpolate the exact solution (Assuming mfu is a Lagrange fem) a = 8.
pidright = np.compress((abs(pts[0, :] - 1.0) < 1e-7), list(range(0, m.nbpts()))) fidright = m.faces_from_pid(pidright) normals = m.normal_of_faces(fidright) fidright = fidright[:, abs(normals[0, :] - 1.0) < 1e-3] GAMMAN = 3 m.set_region(GAMMAN, fidright) #% Definition of the finite element methods ls = gf.LevelSet(m, ls_degree) mls = gf.MeshLevelSet(m) mls.add(ls) mf_ls = ls.mf() if N == 2: mimls = gf.MeshIm(m, gf.Integ('IM_TRIANGLE(4)')) else: mimls = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) mf_basic = gf.MeshFem(m, N) mf_basic.set_fem(gf.Fem(f'FEM_PK({N},{k})')) mf_g = gf.MeshFem(m, 1) mf_g.set_fem(gf.Fem(f'FEM_PK_DISCONTINUOUS({N},{k-1})')) mf_cont = gf.MeshFem(m, 1) mf_cont.set_fem(gf.Fem(f'FEM_PK({N},{ls_degree})')) print(f'There is {mf_basic.nbdof()} elasticity dofs') Mcont = gf.asm_mass_matrix(mimls, mf_cont)
with_graphics = True try: import getfem_tvtk except: print "\n** Could NOT import getfem_tvtk -- graphical output disabled **\n" import time time.sleep(2) with_graphics = False L = 100 H = 20 m = gf.Mesh('triangles grid', np.arange(0, L + 0.01, 4), np.arange(0, H + 0.01, 2)) mim = gf.MeshIm(m, gf.Integ('IM_TRIANGLE(6)')) mfu = gf.MeshFem(m, 2) mfsigma = gf.MeshFem(m, 4) mfd = gf.MeshFem(m) mf0 = gf.MeshFem(m) mfdu = gf.MeshFem(m) mfu.set_fem(gf.Fem('FEM_PK(2,1)')) mfsigma.set_fem(gf.Fem('FEM_PK_DISCONTINUOUS(2,1)')) mfd.set_fem(gf.Fem('FEM_PK(2,1)')) mf0.set_fem(gf.Fem('FEM_PK(2,0)')) mfdu.set_fem(gf.Fem('FEM_PK_DISCONTINUOUS(2,1)')) Lambda = 121150 Mu = 80769 von_mises_threshold = 4000
R = 0.19 #rand() * 0.09 + 0.02 ULS2 = np.minimum(ULS2, ((x - xc) * n[0] + (y - yc) * n[1])) #ULS2s = np.minimum(ULS2s, ((x - xc)**2 + (y - yc)**2) - R**2) ULS2s = np.minimum(ULS2s, (abs(y - yc) + abs(x - xc) - R)) ls2.set_values(ULS2, ULS2s) # '-y-x+.2') # '(y-.2)^2 - 0.04') mls = gf.MeshLevelSet(m) mls.add(ls) mls.add(ls2) mls.adapt() mls.cut_mesh().export_to_pos('ver.pos') mim_bound = gf.MeshIm('levelset', mls, 'boundary(a+b)', gf.Integ('IM_TRIANGLE(6)')) #, gf.Integ('IM_QUAD(5)')) mim = gf.MeshIm('levelset', mls, 'all(a+b)', gf.Integ('IM_TRIANGLE(6)')) mim.set_integ(4) mfu0 = gf.MeshFem(m, 2) mfu0.set_fem(gf.Fem('FEM_QK(2,3)')) mfdu = gf.MeshFem(m, 1) mfdu.set_fem(gf.Fem('FEM_QK_DISCONTINUOUS(2,2)')) mf_mult = gf.MeshFem(m, 2) mf_mult.set_fem(gf.Fem('FEM_QK(2,1)')) A = gf.asm('volumic', 'V()+=comp()', mim_bound) #mls.cut_mesh().export_to_pos('mls.pos','cut mesh')
np.square(DOFpts[1, :] + 0.375) <= 0.1**2)[0] mf_sing_u2 = gf.MeshFem('global function', m, ls2, [ck0, ck1, ck2, ck3], 1) mf_xfem_sing2 = gf.MeshFem('product', mf_part_unity, mf_sing_u2) mf_xfem_sing2.set_enriched_dofs(np.union1d(Idofs_up, Idofs_down)) if variant == 2: mf_u = gf.MeshFem('sum', mf_xfem_sing, mfls_u) else: mf_u = gf.MeshFem('sum', mf_xfem_sing, mf_xfem_sing2, mfls_u) mf_u.set_qdim(2) # MeshIm definition (MeshImLevelSet): mim = gf.MeshIm( 'levelset', mls, 'all', gf.Integ('IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),3)'), gf.Integ('IM_STRUCTURED_COMPOSITE(IM_GAUSS_PARALLELEPIPED(2,6),9)'), gf.Integ('IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),5)')) # Exact solution for a single crack: mf_ue = gf.MeshFem('global function', m, ls, [ck0, ck1, ck2, ck3]) A = 2 + 2 * Mu / (Lambda + 2 * Mu) B = -2 * (Lambda + Mu) / (Lambda + 2 * Mu) Ue = np.zeros([2, 4]) Ue[0, 0] = 0 Ue[1, 0] = A - B # sin(theta/2) Ue[0, 1] = A + B Ue[1, 1] = 0 # cos(theta/2) Ue[0, 2] = -B Ue[1, 2] = 0 # sin(theta/2)*sin(theta) Ue[0, 3] = 0
import getfem as gf import numpy as np # creation of a simple cartesian mesh m = gf.Mesh('cartesian', np.arange(0,1.1,0.1), np.arange(0,1.1,0.1)) # create a MeshFem of for a field of dimension 1 (i.e. a scalar field) mf = gf.MeshFem(m, 1) # assign the Q2 fem to all convexes of the MeshFem mf.set_fem(gf.Fem('FEM_QK(2,2)')) # view the expression of its basis functions on the reference convex print gf.Fem('FEM_QK(2,2)').poly_str() # an exact integration will be used mim = gf.MeshIm(m, gf.Integ('IM_EXACT_PARALLELEPIPED(2)')) # detect the border of the mesh border = m.outer_faces() # mark it as boundary #42 m.set_region(42, border) # empty real model md = gf.Model('real') # declare that "u" is an unknown of the system # on the finite element method `mf` md.add_fem_variable('u', mf) # add generic elliptic brick on "u" md.add_Laplacian_brick(mim, 'u');
mfu.set_classical_fem(u_degree) mfd = gf.MeshFem(m, 1) mfd.set_classical_fem(u_degree) mflambda = gf.MeshFem(m, 1) # used only by version 5 to 13 mflambda.set_classical_fem(lambda_degree) mfvm = gf.MeshFem(m, 1) mfvm.set_classical_discontinuous_fem(u_degree - 1) # Integration method mim = gf.MeshIm(m, 4) if d == 2: mim_friction = gf.MeshIm( m, gf.Integ('IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(4),4)')) else: mim_friction = gf.MeshIm( m, gf.Integ('IM_STRUCTURED_COMPOSITE(IM_TETRAHEDRON(5),4)')) # Volumic density of force nbdofd = mfd.nbdof() nbdofu = mfu.nbdof() F = np.zeros(nbdofd * d) F[d - 1:nbdofd * d:d] = -vertical_force # Elasticity model md = gf.Model('real') md.add_fem_variable('u', mfu) md.add_initialized_data('cmu', [cmu]) md.add_initialized_data('clambda', [clambda])
mfu = gf.MeshFem(m, 1) mfrhs = gf.MeshFem(m, 1) # assign the Lagrange linear fem to all pyramids of the both MeshFem mfu.set_fem(gf.Fem('FEM_PYRAMID_LAGRANGE(2)')) mfrhs.set_fem(gf.Fem('FEM_PYRAMID_LAGRANGE(2)')) # mfu.set_fem(gf.Fem('FEM_PK(3,1)')) # mfrhs.set_fem(gf.Fem('FEM_PK(3,1)')) if (export_mesh): m.export_to_vtk('mesh.vtk') print('\nYou can view the mesh for instance with') print('mayavi2 -d mesh.vtk -f ExtractEdges -m Surface \n') # Integration method used # mim = gf.MeshIm(m, gf.Integ('IM_PYRAMID_COMPOSITE(IM_TETRAHEDRON(6))')) mim = gf.MeshIm(m, gf.Integ('IM_PYRAMID(IM_GAUSS_PARALLELEPIPED(3,3))')) # mim = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) # Boundary selection flst = m.outer_faces() fnor = m.normal_of_faces(flst) tleft = abs(fnor[1, :] + 1) < 1e-14 ttop = abs(fnor[0, :] - 1) < 1e-14 fleft = np.compress(tleft, flst, axis=1) ftop = np.compress(ttop, flst, axis=1) fneum = np.compress(True - ttop - tleft, flst, axis=1) # Mark it as boundary DIRICHLET_BOUNDARY_NUM1 = 1 DIRICHLET_BOUNDARY_NUM2 = 2 NEUMANN_BOUNDARY_NUM = 3
gf.MeshFem("product", mf_part_unity, gf.MeshFem("global function", m, ls, ck, 1)) for ls in [ls1, ls2] ] mf_sing[0].set_enriched_dofs(np.union1d(ctip_dofs[0], ctip_dofs[1])) mf_sing[1].set_enriched_dofs(np.union1d(ctip_dofs[2], ctip_dofs[3])) mf_u = gf.MeshFem("sum", mf_sing[0], mf_sing[1], mfls) mf_u.set_qdim(2) mf_theta = gf.MeshFem("sum", mf_sing[0], mf_sing[1], mfls) # MeshIm definition (MeshImLevelSet): if (quad): mim = gf.MeshIm( "levelset", mls, "all", gf.Integ("IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),5)"), gf.Integ("IM_STRUCTURED_COMPOSITE(IM_GAUSS_PARALLELEPIPED(2,6),9)"), gf.Integ("IM_GAUSS_PARALLELEPIPED(2,4)")) else: mim = gf.MeshIm( "levelset", mls, "all", gf.Integ("IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),3)"), gf.Integ("IM_STRUCTURED_COMPOSITE(IM_GAUSS_PARALLELEPIPED(2,6),9)"), gf.Integ("IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),5)")) mim_bound = [ gf.MeshIm("levelset", mls, boundary, gf.Integ("IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(6),3)")) for boundary in ["boundary(a)", "boundary(b)"] ]
def import_fem2(sico): """ Build a mesh object using getfem. We use getfem++ to build the finite element model and to fill in the operators required by siconos: - the mass matrix (Mass) - the stiffness matrix (Stiff) - the matrix that links global coordinates and local coord. at contact points (H) """ ############################ # The geometry and the mesh ############################ dimX = 10.01 dimY = 10.01 dimZ = 10.01 stepX = 1.0 stepY = 1.0 stepZ = 1.0 x = np.arange(0, dimX, stepX) y = np.arange(0, dimY, stepY) z = np.arange(0, dimZ, stepZ) m = gf.Mesh('regular simplices', x, y, z) m.set('optimize_structure') # Export the mesh to vtk m.export_to_vtk("BlockMesh.vtk") # Create MeshFem objects # (i.e. assign elements onto the mesh for each variable) mfu = gf.MeshFem(m, 3) # displacement mfd = gf.MeshFem(m, 1) # data mff = gf.MeshFem(m, 1) # for plot von-mises # assign the FEM mfu.set_fem(gf.Fem('FEM_PK(3,1)')) mfd.set_fem(gf.Fem('FEM_PK(3,0)')) mff.set_fem(gf.Fem('FEM_PK_DISCONTINUOUS(3,1,0.01)')) # mfu.export_to_vtk("BlockMeshDispl.vtk") # Set the integration method mim = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) # Summary print(' ==================================== \n Mesh details: ') print(' Problem dimension:', mfu.qdim(), '\n Number of elements: ', m.nbcvs(), '\n Number of nodes: ', m.nbpts()) print(' Number of dof: ', mfu.nbdof(), '\n Element type: ', mfu.fem()[0].char()) print(' ====================================') ########################### # Set the parameters # for the constitutive law ########################### E = 1e3 # Young modulus Nu = 0.3 # Poisson coef. # Lame coeff. Lambda = E * Nu / ((1 + Nu) * (1 - 2 * Nu)) Mu = E / (2 * (1 + Nu)) # Density Rho = 7800 ############################ # Boundaries detection ############################ allPoints = m.pts() # Bottom points and faces cbot = (abs(allPoints[2, :]) < 1e-6) pidbot = np.compress(cbot, list(range(0, m.nbpts()))) fbot = m.faces_from_pid(pidbot) BOTTOM = 1 m.set_region(BOTTOM, fbot) # Top points and faces ctop = (abs(allPoints[2, :]) > dimZ - stepZ) pidtop = np.compress(ctop, list(range(0, m.nbpts()))) ftop = m.faces_from_pid(pidtop) TOP = 2 m.set_region(TOP, ftop) # Top-Left points and faces cleft = (abs(allPoints[1, :]) < 1e-6) clefttop = cleft * ctop pidlefttop = np.compress(clefttop, list(range(0, m.nbpts()))) flefttop = m.faces_from_pid(pidlefttop) pidleft = np.compress(cleft, list(range(0, m.nbpts()))) fleft = m.faces_from_pid(pidleft) LEFTTOP = 3 m.set_region(LEFTTOP, flefttop) LEFT = 4 m.set_region(LEFT, fleft) ############################ # Assembly ############################ nbd = mfd.nbdof() # Stiffness matrix sico.Stiff = gf.asm_linear_elasticity(mim, mfu, mfd, np.repeat([Lambda], nbd), np.repeat([Mu], nbd)) # Mass matrix sico.Mass = Rho * gf.asm_mass_matrix(mim, mfu) # Right-hand side Ftop = gf.asm_boundary_source(TOP, mim, mfu, mfd, np.repeat([[0], [0], [-1]], nbd, 1)) Fleft = gf.asm_boundary_source(LEFT, mim, mfu, mfd, np.repeat([[0], [10], [0]], nbd, 1)) sico.RHS = Ftop + Fleft sico.nbdof = mfu.nbdof() sico.q0 = mfu.basic_dof_from_cvid() sico.bot = pidbot # H-Matrix fillH(pidbot, sico, mfu.nbdof()) return m
d = 1.000e+00 x = 1.000e+00 y = 1.000e+00 z = 1.000e+00 m = gf.Mesh('cartesian Q1', np.arange(0., x + d, d), np.arange(0., y + d, d), np.arange(0., z + d, d)) m.set('optimize_structure') print "create a MeshFem object" mfu = gf.MeshFem(m, 3) # displacement print "assign the FEM" mfu.set_fem(gf.Fem('FEM_QK(3,1)')) print "build a MeshIm object" mim = gf.MeshIm(m, gf.Integ('IM_HEXAHEDRON(5)')) print "detect some boundary of the mesh" P = m.pts() ctop = (abs(P[0, :] - 0.) < 1e-6) cbot = (abs(P[1, :] - 0.) < 1e-6) pidtop = np.compress(ctop, range(0, m.nbpts())) pidbot = np.compress(cbot, range(0, m.nbpts())) ftop = m.faces_from_pid(pidtop) fbot = m.faces_from_pid(pidbot) print "create boundary region" NEUMANN_BOUNDARY = 1 DIRICHLET_BOUNDARY = 2 m.set_region(NEUMANN_BOUNDARY, ftop) m.set_region(DIRICHLET_BOUNDARY, fbot)
def import_fem(sico): """ Build a mesh object using getfem. We use getfem++ to build the finite element model and to fill in the operators required by siconos: - the mass matrix (Mass) - the stiffness matrix (Stiff) - the matrix that links global coordinates and local coord. at contact points (H) """ ############################ # The geometry and the mesh ############################ dimX = 10.01 dimY = 10.01 dimZ = 3.01 stepX = 1.0 stepY = 1.0 stepZ = 1.0 x = np.arange(0, dimX, stepX) y = np.arange(0, dimY, stepY) z = np.arange(0, dimZ, stepZ) m = gf.Mesh('regular simplices', x, y, z) m.set('optimize_structure') # Export the mesh to vtk m.export_to_vtk("BlockMesh.vtk") # Create MeshFem objects # (i.e. assign elements onto the mesh for each variable) mfu = gf.MeshFem(m, 3) # displacement mfd = gf.MeshFem(m, 1) # data mff = gf.MeshFem(m, 1) # for plot von-mises # assign the FEM mfu.set_fem(gf.Fem('FEM_PK(3,1)')) mfd.set_fem(gf.Fem('FEM_PK(3,0)')) mff.set_fem(gf.Fem('FEM_PK_DISCONTINUOUS(3,1,0.01)')) # mfu.export_to_vtk("BlockMeshDispl.vtk") # Set the integration method mim = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) # Summary print(' ==================================== \n Mesh details: ') print(' Problem dimension:', mfu.qdim(), '\n Number of elements: ', m.nbcvs(), '\n Number of nodes: ', m.nbpts()) print(' Number of dof: ', mfu.nbdof(), '\n Element type: ', mfu.fem()[0].char()) print(' ====================================') ########################### # Set the parameters # for the constitutive law ########################### E = 1e3 # Young modulus Nu = 0.3 # Poisson coef. # Lame coeff. Lambda = E * Nu / ((1 + Nu) * (1 - 2 * Nu)) Mu = E / (2 * (1 + Nu)) # Density Rho = 1.0 #7.800 Gravity = -9.81 ############################ # Boundaries detection ############################ allPoints = m.pts() # Bottom points and faces cbot = (abs(allPoints[2, :]) < 1e-6) pidbot = np.compress(cbot, list(range(0, m.nbpts()))) fbot = m.faces_from_pid(pidbot) BOTTOM = 1 m.set_region(BOTTOM, fbot) # Top points and faces ctop = (abs(allPoints[2, :]) > dimZ - stepZ) pidtop = np.compress(ctop, list(range(0, m.nbpts()))) ftop = m.faces_from_pid(pidtop) TOP = 2 m.set_region(TOP, ftop) # Top-Left points and faces cleft = (abs(allPoints[1, :]) < 1e-6) clefttop = cleft * ctop pidlefttop = np.compress(clefttop, list(range(0, m.nbpts()))) flefttop = m.faces_from_pid(pidlefttop) pidleft = np.compress(cleft, list(range(0, m.nbpts()))) fleft = m.faces_from_pid(pidleft) LEFTTOP = 3 m.set_region(LEFTTOP, flefttop) LEFT = 4 m.set_region(LEFT, fleft) # Create a model md = gf.Model('real') md.add_fem_variable('u', mfu) md.add_initialized_data('lambda', Lambda) md.add_initialized_data('mu', Mu) md.add_initialized_data('source_term', [0, 0, -100]) md.add_initialized_data('push', [0, 100, 0]) md.add_initialized_data('rho', Rho) md.add_initialized_data('gravity', Gravity) # Weight = np.zeros(mfu.nbdof()) ## Weight = [] md.add_initialized_data('weight', [0, 0, Rho * Gravity]) md.add_isotropic_linearized_elasticity_brick(mim, 'u', 'lambda', 'mu') #md.add_source_term_brick(mim,'u','source_term',TOP) #md.add_source_term_brick(mim,'u','push',LEFT) md.add_source_term_brick(mim, 'u', 'weight') #md.add_Dirichlet_condition_with_multipliers(mim,'u',mfu,BOTTOM) md.assembly() sico.Stiff = md.tangent_matrix() sico.RHS = md.rhs() sico.q0 = md.variable('u') md2 = gf.Model('real') md2.add_fem_variable('u', mfu) md2.add_initialized_data('rho', Rho) md2.add_mass_brick(mim, 'u', 'rho') md2.assembly() sico.Mass = md2.tangent_matrix() sico.nbdof = mfu.nbdof() sico.mfu = mfu sico.mesh = m sico.pos = np.zeros(sico.nbdof) sico.pos[0:sico.nbdof:3] = m.pts()[0, :] sico.pos[1:sico.nbdof:3] = m.pts()[1, :] sico.pos[2:sico.nbdof:3] = m.pts()[2, :] sico.K0 = np.dot(sico.Stiff.full(), sico.pos) sico.bot = pidbot # running solve... #md.solve() # post-processing #VM=md.compute_isotropic_linearized_Von_Mises_or_Tresca('u','lambda','mu',mff) # extracted solution #U = md.variable('u') # export U and VM in a pos file #sl = gf.Slice(('boundary',),mfu,1) #sl.export_to_vtk('toto.vtk', mfu, U, 'Displacement', mff, VM, 'Von Mises Stress') # H-Matrix fillH(pidbot, sico, mfu.nbdof()) return md
mesh.set_region(LEFT_BOUND, fb1) mesh.set_region(BOTTOM_BOUND, fb2) mesh.set_region(AUX_BOUND1, fb3) mesh.set_region(AUX_BOUND2, fb4) mesh.region_subtract(LEFT_BOUND, AUX_BOUND2) mesh.region_subtract(BOTTOM_BOUND, AUX_BOUND1) # Create a MeshFem for u and rhs fields of dimension 1 (i.e. a scalar field) mfu = gf.MeshFem(mesh, 1) mfP0 = gf.MeshFem(mesh, 1) # Assign the discontinuous P2 fem to all convexes of the both MeshFem mfu.set_fem(gf.Fem('FEM_PK(2,2)')) mfP0.set_fem(gf.Fem('FEM_PK(2,0)')) # Integration method used mim = gf.MeshIm(mesh, gf.Integ('IM_TRIANGLE(4)')) # Inner edges for the computation of the normal derivative jump in_faces = mesh.inner_faces() INNER_FACES = 18 mesh.set_region(INNER_FACES, in_faces) # Model md = gf.Model('real') # Main unknown md.add_fem_variable('u', mfu) # Laplacian term on u md.add_Laplacian_brick(mim, 'u')
# mfu1 = gf.MeshFem(mesh1, 2) mfu1.set_classical_fem(elements_degree) mflambda = gf.MeshFem(mesh1, 2) mflambda.set_classical_fem(elements_degree - 1) mflambda_C = gf.MeshFem(mesh1, 1) mflambda_C.set_classical_fem(elements_degree - 1) mfu2 = gf.MeshFem(mesh2, 2) mfu2.set_classical_fem(elements_degree) mfvm1 = gf.MeshFem(mesh1, 1) mfvm1.set_classical_discontinuous_fem(elements_degree) mfvm2 = gf.MeshFem(mesh2, 1) mfvm2.set_classical_discontinuous_fem(elements_degree) mim1 = gf.MeshIm(mesh1, 4) mim1c = gf.MeshIm(mesh1, gf.Integ('IM_STRUCTURED_COMPOSITE(IM_TRIANGLE(4),2)')) mim2 = gf.MeshIm(mesh2, 4) # # Model definition # md = gf.Model('real') md.add_fem_variable('u1', mfu1) # Displacement of the structure 1 md.add_fem_variable('u2', mfu2) # Displacement of the structure 2 md.add_initialized_data('cmu', [cmu]) md.add_initialized_data('clambdastar', [clambdastar]) md.add_isotropic_linearized_elasticity_brick(mim1, 'u1', 'clambdastar', 'cmu') md.add_isotropic_linearized_elasticity_brick(mim2, 'u2', 'clambdastar', 'cmu') md.add_Dirichlet_condition_with_multipliers(mim2, 'u2', elements_degree - 1,
# create a Mesh object (importing) m = gf.Mesh('import', 'gid', file_msh) m.set('optimize structure') # create a MeshFem object mfu = gf.MeshFem(m, 3) # displacement mfd = gf.MeshFem(m, 1) # data mfe = gf.MeshFem(m, 1) # for plot von-mises # assign the FEM mfu.set_fem(gf.Fem('FEM_PK(3,%d)' % (degree, ))) mfd.set_fem(gf.Fem('FEM_PK(3,0)')) mfe.set_fem(gf.Fem('FEM_PK_DISCONTINUOUS(3,%d,0.01)' % (degree, ))) # build a MeshIm object mim = gf.MeshIm(m, gf.Integ('IM_TETRAHEDRON(5)')) print 'nbcvs=%d, nbpts=%d, qdim=%d, fem = %s, nbdof=%d' % \ (m.nbcvs(), m.nbpts(), mfu.qdim(), mfu.fem()[0].char(), mfu.nbdof()) # detect some boundary of the mesh P = m.pts() ctop = (abs(P[1, :] - 13) < 1e-6) cbot = (abs(P[1, :] + 10) < 1e-6) pidtop = np.compress(ctop, range(0, m.nbpts())) pidbot = np.compress(cbot, range(0, m.nbpts())) ftop = m.faces_from_pid(pidtop) fbot = m.faces_from_pid(pidbot) # create boundary region NEUMANN_BOUNDARY = 1 DIRICHLET_BOUNDARY = 2
mls = gf.MeshLevelSet(m) ls = gf.LevelSet(m, ls_degree) mls.add(ls) mf_ls = ls.mf() P = mf_ls.basic_dof_nodes() x = P[0] y = P[1] ULS = 1000*np.ones(x.shape) #% Loop on the topological optimization #while True: for col in range(1000): ls.set_values(ULS) mls.adapt() mim_bound = gf.MeshIm('levelset',mls,'boundary', gf.Integ('IM_TRIANGLE(6)')) mim = gf.MeshIm('levelset',mls,'outside', gf.Integ('IM_TRIANGLE(6)')) mim.set_integ(4) mf_mult = gf.MeshFem(m) mf_mult.set_fem(gf.Fem('FEM_QK(2,1)')) M = gf.asm_mass_matrix(mim, mf_basic) D = np.abs(M.diag().T[0]) ind = np.argwhere(D>1e-8) mf = gf.MeshFem('partial', mf_basic, ind) S = gf.asm('volumic','V()+=comp()',mim) print('remaining surface :',S) # % Problem definition (Laplace(u) + u = f)