def test_polynomial_ET_Segm(domain, alpha): order = alpha m = ngm.Mesh() m.dim = 1 nel = 1 pnums = [] for i in range(0, nel+1): pnums.append (m.Add (ngm.MeshPoint (ngm.Pnt(i/nel, 0, 0)))) for i in range(0,nel): m.Add (ngm.Element1D ([pnums[i],pnums[i+1]], index=1)) m.Add (ngm.Element0D (pnums[0], index=1)) m.Add (ngm.Element0D (pnums[nel], index=2)) mesh = Mesh(m) x_ast = 0.78522 levelset = x_ast-x referencevals = {POS:pow(x_ast, alpha+1)/(alpha+1), NEG:(1-pow(x_ast, alpha+1))/(alpha+1), IF: pow(x_ast, alpha)} V = H1(mesh, order=1) lset_approx = GridFunction(V) #InterpolateToP1(levelset,lset_approx) lset_approx.Set(levelset) f = x**alpha integral = Integrate(levelset_domain = { "levelset" : lset_approx, "domain_type" : domain}, cf=f, mesh=mesh, order = order) print("Result of Integration Key ",domain," : ", integral) error = abs(integral - referencevals[domain]) print("Error: ", error) assert error < 5e-15*(order+1)*(order+1)
def ngsolve_vector_array_factory(length, dim, seed): if dim not in NGSOLVE_spaces: mesh = ngmsh.Mesh(dim=1) if dim > 0: pids = [] for i in range(dim + 1): pids.append( mesh.Add(ngmsh.MeshPoint(ngmsh.Pnt(i / dim, 0, 0)))) for i in range(dim): mesh.Add(ngmsh.Element1D([pids[i], pids[i + 1]], index=1)) NGSOLVE_spaces[dim] = NGSolveVectorSpace( ngs.L2(ngs.Mesh(mesh), order=0)) U = NGSOLVE_spaces[dim].zeros(length) np.random.seed(seed) for v, a in zip(U._list, np.random.random((length, dim))): v.to_numpy()[:] = a if np.random.randint(2): UU = NGSOLVE_spaces[dim].zeros(length) for v, a in zip(UU._list, np.random.random((length, dim))): v.real_part.to_numpy()[:] = a for u, uu in zip(U._list, UU._list): u.imag_part = uu.real_part return U
def _create_ngsolve_space(dim): if dim not in _NGSOLVE_spaces: mesh = ngmsh.Mesh(dim=1) if dim > 0: pids = [] for i in range(dim + 1): pids.append(mesh.Add(ngmsh.MeshPoint(ngmsh.Pnt(i / dim, 0, 0)))) for i in range(dim): mesh.Add(ngmsh.Element1D([pids[i], pids[i + 1]], index=1)) _NGSOLVE_spaces[dim] = NGSolveVectorSpace(ngs.L2(ngs.Mesh(mesh), order=0)) return _NGSOLVE_spaces[dim]
def test_1dlaplace(): m = meshing.Mesh() m.dim = 1 nel = 20 pnums = [] for i in range(0, nel + 1): pnums.append(m.Add(meshing.MeshPoint(meshing.Pnt(i / nel, 0, 0)))) for i in range(0, nel): m.Add(meshing.Element1D([pnums[i], pnums[i + 1]], index=1)) m.Add(meshing.Element0D(pnums[0], index=1)) m.Add(meshing.Element0D(pnums[nel], index=2)) mesh = Mesh(m) order = 10 fes = H1(mesh, order=order, dirichlet=[1, 2]) u = fes.TrialFunction() v = fes.TestFunction() n = specialcf.normal(mesh.dim) h = specialcf.mesh_size ugf = GridFunction(fes) uex = GridFunction(fes) uex.Set(sin(pi * x)) a = BilinearForm(fes) a += SymbolicBFI(grad(u) * grad(v)) l = LinearForm(fes) l += SymbolicLFI(pi * pi * uex * v) l.Assemble() a.Assemble() invmat = a.mat.Inverse(fes.FreeDofs()) ugf.vec.data = invmat * l.vec error = sqrt(Integrate((ugf - uex) * (ugf - uex), mesh)) assert error <= 1e-14
def MakeMesh1D(): a = 0 b = 1 nel = 10 m = msh.Mesh() m.dim = 1 pnums = [] for i in range(nel + 1): pnums.append(m.Add(msh.MeshPoint(msh.Pnt(a + (b - a) * i / nel, 0, 0)))) for i in range(2): m.Add(msh.Element1D([pnums[i], pnums[i + 1]], index=1)) for i in range(2, 5): m.Add(msh.Element1D([pnums[i], pnums[i + 1]], index=3)) for i in range(5, 7): m.Add(msh.Element1D([pnums[i], pnums[i + 1]], index=1)) for i in range(7, nel): m.Add(msh.Element1D([pnums[i], pnums[i + 1]], index=2)) m.SetMaterial(1, 'base') m.SetMaterial(2, 'chip') m.SetMaterial(3, 'top') # add points m.Add(msh.Element0D(pnums[0], index=1)) m.Add(msh.Element0D(pnums[2], index=2)) m.Add(msh.Element0D(pnums[5], index=2)) m.Add(msh.Element0D(pnums[7], index=2)) m.Add(msh.Element0D(pnums[nel], index=2)) # set boundary condition names m.SetBCName(0, 'bottom') m.SetBCName(1, 'other') m.Save('temp.vol') return m
visoptions.scaledeform1 = '100' ## 1D Mesh m = ngm.Mesh() m.dim = 1 n_elems = 1000 x_min = -50 x_max = 50 length = x_max - x_min pnums = [] xs = [] for i in range(0, n_elems + 1): pnt_x = x_min + length * i / n_elems xs.append(pnt_x) pnums.append(m.Add(ngm.MeshPoint(ngm.Pnt(pnt_x, 0, 0)))) for i in range(0, n_elems): m.Add(ngm.Element1D([pnums[i], pnums[i + 1]], index=1)) m.SetMaterial(1, 'material') m.Add(ngm.Element0D(pnums[0], index=1)) m.Add(ngm.Element0D(pnums[n_elems], index=2)) ## NGSolve mesh = ngs.Mesh(m) fes = ngs.H1(mesh, order=1, dirichlet=[1, 2], complex=True) u = fes.TrialFunction() v = fes.TestFunction()
def get_Netgen_nonconformal(N, scale, offset, dim=2): """ Generate a structured quadrilateral/hexahedral NGSolve mesh over a prescribed square/cubic domain. Args: N (list): Number of mesh elements in each direction (N+1 nodes). scale (list): Extent of the meshed domain in each direction ([-2,2] square -> scale=[4,4]). offset (list): Centers the meshed domain in each direction ([-2,2] square -> offset=[2,2]). dim (int): Dimension of the domain (must be 2 or 3). Returns: mesh (Netgen mesh): Structured quadrilateral/hexahedral Netgen mesh. """ # Construct a Netgen mesh. ngmesh = ngmsh.Mesh() if dim == 2: ngmesh.SetGeometry(unit_square) ngmesh.dim = 2 # Set evenly spaced mesh nodes. points = [] for i in range(N[1] + 1): for j in range(N[0] + 1): x = -offset[0] + scale[0] * j / N[0] y = -offset[1] + scale[1] * i / N[1] z = 0 points.append(ngmesh.Add(ngmsh.MeshPoint(ngmsh.Pnt(x, y, z)))) # TODO: Should the user be able to set their own BC names? idx_dom = ngmesh.AddRegion('dom', dim=2) idx_bottom = ngmesh.AddRegion('bottom', dim=1) idx_right = ngmesh.AddRegion('right', dim=1) idx_top = ngmesh.AddRegion('top', dim=1) idx_left = ngmesh.AddRegion('left', dim=1) # Generate mesh faces. for i in range(N[1]): for j in range(N[0]): p1 = i * (N[0] + 1) + j p2 = i * (N[0] + 1) + j + 1 p3 = i * (N[0] + 1) + j + 2 + N[0] p4 = i * (N[0] + 1) + j + 1 + N[0] ngmesh.Add(ngmsh.Element2D(idx_dom, [points[p1], points[p2], points[p3], points[p4]])) # Assign each edge of the domain to the same boundary. for i in range(N[1]): ngmesh.Add(ngmsh.Element1D([points[N[0] + i * (N[0] + 1)], points[N[0] + (i + 1) * (N[0] + 1)]], index=idx_right)) ngmesh.Add(ngmsh.Element1D([points[(i + 1) * (N[0] + 1)], points[i * (N[0] + 1)]], index=idx_left)) for i in range(N[0]): ngmesh.Add(ngmsh.Element1D([points[i], points[i + 1]], index=idx_bottom)) ngmesh.Add(ngmsh.Element1D([points[1 + i + N[1] * (N[0] + 1)], points[i + N[1] * (N[0] + 1)]], index=idx_top)) elif dim == 3: ngmesh.dim = 3 p1 = (0, 0, 0) p2 = (1, 1, 1) cube = ngcsg.OrthoBrick(ngcsg.Pnt(p1[0], p1[1], p1[2]), ngcsg.Pnt(p2[0], p2[1], p2[2])).bc(1) geo = ngcsg.CSGeometry() geo.Add(cube) ngmesh.SetGeometry(geo) # Set evenly spaced mesh nodes. points = [] for i in range(N[0] + 1): for j in range(N[1] + 1): for k in range(N[2] + 1): x = -offset[0] + scale[0] * i / N[0] y = -offset[1] + scale[1] * j / N[1] z = -offset[2] + scale[2] * k / N[2] points.append(ngmesh.Add(ngmsh.MeshPoint(ngmsh.Pnt(x, y, z)))) # Generate mesh cells. for i in range(N[0]): for j in range(N[1]): for k in range(N[2]): base = i * (N[1] + 1) * (N[2] + 1) + j * (N[2] + 1) + k baseup = base + (N[1] + 1) * (N[2] + 1) p1 = base p2 = base + 1 p3 = base + (N[2] + 1) + 1 p4 = base + (N[2] + 1) p5 = baseup p6 = baseup + 1 p7 = baseup + (N[2] + 1) + 1 p8 = baseup + (N[2] + 1) idx = 1 ngmesh.Add(ngmsh.Element3D(idx, [points[p1], points[p2], points[p3], points[p4], points[p5], points[p6], points[p7], points[p8]])) def add_bc(p, d, N, deta, neta, facenr): def add_seg(i, j, os): base = p + i * d + j * deta p1 = base p2 = base + os ngmesh.Add(ngmsh.Element1D([points[p1], points[p2]], index=facenr)) return for i in range(N): for j in [0, neta]: add_seg(i, j, d) for i in [0, N]: for j in range(neta): add_seg(i, j, deta) for i in range(N): for j in range(neta): base = p + i * d + j * deta p1 = base p2 = base + d p3 = base + d + deta p4 = base + deta ngmesh.Add(ngmsh.Element2D(facenr, [points[p1], points[p2], points[p3], points[p4]])) return # Order is important! ngmesh.Add(ngmsh.FaceDescriptor(surfnr=4, domin=1, bc=1)) ngmesh.Add(ngmsh.FaceDescriptor(surfnr=2, domin=1, bc=2)) ngmesh.Add(ngmsh.FaceDescriptor(surfnr=5, domin=1, bc=3)) ngmesh.Add(ngmsh.FaceDescriptor(surfnr=3, domin=1, bc=4)) ngmesh.Add(ngmsh.FaceDescriptor(surfnr=0, domin=1, bc=5)) ngmesh.Add(ngmsh.FaceDescriptor(surfnr=1, domin=1, bc=6)) # Assign each exterior face of the domain to its respective boundary. add_bc(0, 1, N[2], N[2] + 1, N[1], 1) add_bc(0, (N[1] + 1) * (N[2] + 1), N[0], 1, N[2], 2) add_bc((N[0] + 1) * (N[1] + 1) * (N[2] + 1) - 1, -(N[2] + 1), N[1], -1, N[2], 3) add_bc((N[0] + 1) * (N[1] + 1) * (N[2] + 1) - 1, -1, N[2], -(N[1] + 1) * (N[2] + 1), N[0], 4) add_bc(0, N[2] + 1, N[1], (N[1] + 1) * (N[2] + 1), N[0], 5) add_bc((N[0] + 1) * (N[1] + 1) * (N[2] + 1) - 1, -(N[1] + 1) * (N[2] + 1), N[0], -(N[2] + 1), N[1], 6) # TODO: Should the user be able to specify their own bc names? bc_names = {0: 'back', 1: 'left', 2: 'front', 3: 'right', 4: 'bottom', 5: 'top'} for key, val in bc_names.items(): ngmesh.SetBCName(key, val) else: raise ValueError('Only works with 2D or 3D meshes.') return ngmesh
def ProdMesh(ngmeshbase, t_steps, dirichletsplit=False): ngmesh = ngm.Mesh() ngmesh.dim = 3 pnums = [] for p in ngmeshbase.Points(): x, y, z = p.p ngmesh.Add(ngm.MeshPoint(ngm.Pnt(x, y, 0))) for i, p in enumerate(ngmeshbase.Points()): x, y, z = p.p pnums.append(ngmesh.Add(ngm.MeshPoint(ngm.Pnt(x, y, t_steps)))) El1d = ngmeshbase.Elements1D() El2d = ngmeshbase.Elements2D() ngmesh.SetMaterial(1, "mat") for el in El2d: ngmesh.Add( ngm.Element3D(1, [ pnums[el.points[0].nr - 1], pnums[el.points[1].nr - 1], pnums[el.points[2].nr - 1], el.points[0].nr, el.points[1].nr, el.points[2].nr ])) fde = ngm.FaceDescriptor(surfnr=1, domin=1, bc=1) fde.bcname = "bottom" fdid = ngmesh.Add(fde) for el in El2d: ngmesh.Add( ngm.Element2D(fdid, [el.points[2].nr, el.points[1].nr, el.points[0].nr])) fde = ngm.FaceDescriptor(surfnr=2, domin=1, bc=2) fde.bcname = "top" fdid = ngmesh.Add(fde) for el in El2d: ngmesh.Add( ngm.Element2D(fdid, [ pnums[el.points[0].nr - 1], pnums[el.points[1].nr - 1], pnums[el.points[2].nr - 1] ])) if dirichletsplit == False: fde = ngm.FaceDescriptor(surfnr=3, domin=1, bc=3) fde.bcname = "dirichlet" fdid = ngmesh.Add(fde) for el in El1d: ngmesh.Add( ngm.Element2D(fdid, [ el.points[0].nr, el.points[1].nr, pnums[el.points[1].nr - 1], pnums[el.points[0].nr - 1] ])) ngmesh.SetBCName(2, "dirichlet") if dirichletsplit == True: fde = ngm.FaceDescriptor(surfnr=3, domin=1, bc=3) fde.bcname = "front" fdid = ngmesh.Add(fde) for el in El1d: if ngmeshbase.Points()[el.points[0]][1] == 0: ngmesh.Add( ngm.Element2D(fdid, [ el.points[0].nr, el.points[1].nr, pnums[el.points[1].nr - 1], pnums[el.points[0].nr - 1] ])) fde = ngm.FaceDescriptor(surfnr=4, domin=1, bc=4) fde.bcname = "back" fdid = ngmesh.Add(fde) for el in El1d: if ngmeshbase.Points()[el.points[0]][1] == 1: ngmesh.Add( ngm.Element2D(fdid, [ el.points[0].nr, el.points[1].nr, pnums[el.points[1].nr - 1], pnums[el.points[0].nr - 1] ])) fde = ngm.FaceDescriptor(surfnr=5, domin=1, bc=5) fde.bcname = "left" fdid = ngmesh.Add(fde) for el in El1d: if ngmeshbase.Points()[el.points[0]][0] == 0: ngmesh.Add( ngm.Element2D(fdid, [ el.points[0].nr, el.points[1].nr, pnums[el.points[1].nr - 1], pnums[el.points[0].nr - 1] ])) fde = ngm.FaceDescriptor(surfnr=6, domin=1, bc=6) fde.bcname = "right" fdid = ngmesh.Add(fde) for el in El1d: if ngmeshbase.Points()[el.points[0]][0] == 1: ngmesh.Add( ngm.Element2D(fdid, [ el.points[0].nr, el.points[1].nr, pnums[el.points[1].nr - 1], pnums[el.points[0].nr - 1] ])) ngmesh.SetBCName(2, "front") ngmesh.SetBCName(3, "back") ngmesh.SetBCName(4, "left") ngmesh.SetBCName(5, "right") ngmesh.SetBCName(0, "bottom") ngmesh.SetBCName(1, "top") mesh = Mesh(ngmesh) return mesh
def CartSquare(N, t_steps, xscale=1, xshift=0, tscale=1): ngmesh = ngm.Mesh() ngmesh.SetGeometry(unit_square) ngmesh.dim = 2 pnums = [] for j in range(t_steps + 1): for i in range(N + 1): pnums.append( ngmesh.Add( ngm.MeshPoint( ngm.Pnt((i / N) * xscale - xshift, (j / t_steps) * tscale, 0)))) foo = ngm.FaceDescriptor(surfnr=1, domin=1, bc=1) ngmesh.Add(foo) ngmesh.SetMaterial(1, "mat") for j in range(t_steps): for i in range(N): ngmesh.Add( ngm.Element2D(1, [ pnums[i + j * (N + 1)], pnums[i + 1 + j * (N + 1)], pnums[i + 1 + (j + 1) * (N + 1)], pnums[i + (j + 1) * (N + 1)] ])) fde = ngm.FaceDescriptor(surfnr=1, domin=1, bc=1) fde.bcname = "bottom" fdid = ngmesh.Add(fde) for i in range(N): ngmesh.Add(ngm.Element1D([pnums[i], pnums[i + 1]], index=1)) fde = ngm.FaceDescriptor(surfnr=2, domin=1, bc=2) fde.bcname = "top" fdid = ngmesh.Add(fde) for i in range(N): ngmesh.Add( ngm.Element1D([ pnums[i + t_steps * (N + 1)], pnums[i + 1 + t_steps * (N + 1)] ], index=2)) fde = ngm.FaceDescriptor(surfnr=3, domin=1, bc=3) fde.bcname = "dirichlet" fdid = ngmesh.Add(fde) for i in range(t_steps): ngmesh.Add( ngm.Element1D( [pnums[N + i * (N + 1)], pnums[N + (i + 1) * (N + 1)]], index=3)) ngmesh.Add( ngm.Element1D( [pnums[0 + i * (N + 1)], pnums[0 + (i + 1) * (N + 1)]], index=3)) ngmesh.SetBCName(0, "bottom") ngmesh.SetBCName(1, "top") ngmesh.SetBCName(2, "dirichlet") mesh = Mesh(ngmesh) # print("boundaries" + str(mesh.GetBoundaries())) return mesh