def test_tangential_onb(ctx_factory): cl_ctx = ctx_factory() queue = cl.CommandQueue(cl_ctx) from meshmode.mesh.generation import generate_torus mesh = generate_torus(5, 2, order=3) discr = Discretization(cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(3)) tob = sym.tangential_onb(mesh.ambient_dim) nvecs = tob.shape[1] # make sure tangential_onb is mutually orthogonal and normalized orth_check = bind( discr, sym.make_obj_array([ np.dot(tob[:, i], tob[:, j]) - (1 if i == j else 0) for i in range(nvecs) for j in range(nvecs) ]))(queue) for i, orth_i in enumerate(orth_check): assert (cl.clmath.fabs(orth_i) < 1e-13).get().all() # make sure tangential_onb is orthogonal to normal orth_check = bind( discr, sym.make_obj_array([ np.dot(tob[:, i], sym.normal(mesh.ambient_dim).as_vector()) for i in range(nvecs) ]))(queue) for i, orth_i in enumerate(orth_check): assert (cl.clmath.fabs(orth_i) < 1e-13).get().all()
def test_tangential_onb(ctx_factory): cl_ctx = ctx_factory() queue = cl.CommandQueue(cl_ctx) from meshmode.mesh.generation import generate_torus mesh = generate_torus(5, 2, order=3) discr = Discretization( cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(3)) tob = sym.tangential_onb(mesh.ambient_dim) nvecs = tob.shape[1] # make sure tangential_onb is mutually orthogonal and normalized orth_check = bind(discr, sym.make_obj_array([ np.dot(tob[:, i], tob[:, j]) - (1 if i == j else 0) for i in range(nvecs) for j in range(nvecs)]) )(queue) for i, orth_i in enumerate(orth_check): assert (cl.clmath.fabs(orth_i) < 1e-13).get().all() # make sure tangential_onb is orthogonal to normal orth_check = bind(discr, sym.make_obj_array([ np.dot(tob[:, i], sym.normal(mesh.ambient_dim).as_vector()) for i in range(nvecs)]) )(queue) for i, orth_i in enumerate(orth_check): assert (cl.clmath.fabs(orth_i) < 1e-13).get().all()
def test_tangential_onb(actx_factory): actx = actx_factory() from meshmode.mesh.generation import generate_torus mesh = generate_torus(5, 2, order=3) discr = Discretization( actx, mesh, InterpolatoryQuadratureSimplexGroupFactory(3)) tob = sym.tangential_onb(mesh.ambient_dim) nvecs = tob.shape[1] # make sure tangential_onb is mutually orthogonal and normalized orth_check = bind(discr, sym.make_obj_array([ np.dot(tob[:, i], tob[:, j]) - (1 if i == j else 0) for i in range(nvecs) for j in range(nvecs)]) )(actx) for orth_i in orth_check: assert actx.to_numpy( actx.np.all(actx.np.abs(orth_i) < 1e-13) ) # make sure tangential_onb is orthogonal to normal orth_check = bind(discr, sym.make_obj_array([ np.dot(tob[:, i], sym.normal(mesh.ambient_dim).as_vector()) for i in range(nvecs)]) )(actx) for orth_i in orth_check: assert actx.to_numpy( actx.np.all(actx.np.abs(orth_i) < 1e-13) )
def operator(self, unknown): sig1, sig2 = unknown lam1, lam2 = self.lambdas S_G = partial(self.S_G, qbx_forced_limit=1) # noqa: N806 c = self.c def Sn_G(i, density): # noqa return self.S_G(i, density, qbx_forced_limit="avg", op_map=partial(sym.normal_derivative, 2)) d = sym.make_obj_array([0.5 * sig1, 0.5 * lam2**2 * sig1 - 0.5 * sig2]) a = sym.make_obj_array([ # A11 Sn_G(1, sig1) + c * S_G(1, sig1) # A12 + Sn_G(0, sig2) + c * S_G(0, sig2), # A21 lam2**2 * Sn_G(1, sig1) # A22 - Sn_G(1, sig2) + lam1**2 * Sn_G(0, sig2) ]) return d + a
def operator(self, unknown): sig1, sig2 = unknown lam1, lam2 = self.lambdas S_G = partial(self.S_G, qbx_forced_limit=1) # noqa: N806 c = self.c def Sn_G(i, density): # noqa return self.S_G(i, density, qbx_forced_limit="avg", op_map=partial(sym.normal_derivative, 2)) d = sym.make_obj_array([ 0.5*sig1, 0.5*lam2**2*sig1 - 0.5*sig2 ]) a = sym.make_obj_array([ # A11 Sn_G(1, sig1) + c*S_G(1, sig1) # A12 + Sn_G(0, sig2) + c*S_G(0, sig2), # A21 lam2**2*Sn_G(1, sig1) # A22 - Sn_G(1, sig2) + lam1**2*Sn_G(0, sig2) ]) return d+a
def test_3d_orientation(ctx_factory, what, mesh_gen_func, visualize=False): pytest.importorskip("pytential") logging.basicConfig(level=logging.INFO) ctx = ctx_factory() queue = cl.CommandQueue(ctx) mesh = mesh_gen_func() logger.info("%d elements" % mesh.nelements) from meshmode.discretization import Discretization discr = Discretization(ctx, mesh, PolynomialWarpAndBlendGroupFactory(1)) from pytential import bind, sym # {{{ check normals point outward if what == "torus": nodes = sym.nodes(mesh.ambient_dim).as_vector() angle = sym.atan2(nodes[1], nodes[0]) center_nodes = sym.make_obj_array([ 5*sym.cos(angle), 5*sym.sin(angle), 0*angle]) normal_outward_expr = ( sym.normal(mesh.ambient_dim) | (nodes-center_nodes)) else: normal_outward_expr = ( sym.normal(mesh.ambient_dim) | sym.nodes(mesh.ambient_dim)) normal_outward_check = bind(discr, normal_outward_expr)(queue).as_scalar() > 0 assert normal_outward_check.get().all(), normal_outward_check.get() # }}} normals = bind(discr, sym.normal(mesh.ambient_dim).xproject(1))(queue) if visualize: from meshmode.discretization.visualization import make_visualizer vis = make_visualizer(queue, discr, 1) vis.write_vtk_file("normals.vtu", [ ("normals", normals), ])
def main(): # cl.array.to_device(queue, numpy_array) from meshmode.mesh.io import generate_gmsh, FileSource mesh = generate_gmsh( FileSource("ellipsoid.step"), 2, order=2, other_options=["-string", "Mesh.CharacteristicLengthMax = %g;" % h]) from meshmode.mesh.processing import perform_flips # Flip elements--gmsh generates inside-out geometry. mesh = perform_flips(mesh, np.ones(mesh.nelements)) print("%d elements" % mesh.nelements) from meshmode.mesh.processing import find_bounding_box bbox_min, bbox_max = find_bounding_box(mesh) bbox_center = 0.5*(bbox_min+bbox_max) bbox_size = max(bbox_max-bbox_min) / 2 logger.info("%d elements" % mesh.nelements) from pytential.qbx import QBXLayerPotentialSource from meshmode.discretization import Discretization from meshmode.discretization.poly_element import \ InterpolatoryQuadratureSimplexGroupFactory density_discr = Discretization( cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(target_order)) qbx = QBXLayerPotentialSource(density_discr, 4*target_order, qbx_order, fmm_order=qbx_order + 10, fmm_backend="fmmlib") from pytential.symbolic.pde.maxwell import MuellerAugmentedMFIEOperator pde_op = MuellerAugmentedMFIEOperator( omega=0.4, epss=[1.4, 1.0], mus=[1.2, 1.0], ) from pytential import bind, sym unk = pde_op.make_unknown("sigma") sym_operator = pde_op.operator(unk) sym_rhs = pde_op.rhs( sym.make_sym_vector("Einc", 3), sym.make_sym_vector("Hinc", 3)) sym_repr = pde_op.representation(0, unk) if 1: expr = sym_repr print(sym.pretty(expr)) print("#"*80) from pytential.target import PointsTarget tgt_points=np.zeros((3,1)) tgt_points[0,0] = 100 tgt_points[1,0] = -200 tgt_points[2,0] = 300 bound_op = bind((qbx, PointsTarget(tgt_points)), expr) print(bound_op.code) if 1: def green3e(x,y,z,source,strength,k): # electric field corresponding to dyadic green's function # due to monochromatic electric dipole located at "source". # "strength" is the the intensity of the dipole. # E = (I + Hess)(exp(ikr)/r) dot (strength) # dx = x - source[0] dy = y - source[1] dz = z - source[2] rr = np.sqrt(dx**2 + dy**2 + dz**2) fout = np.exp(1j*k*rr)/rr evec = fout*strength qmat = np.zeros((3,3),dtype=np.complex128) qmat[0,0]=(2*dx**2-dy**2-dz**2)*(1-1j*k*rr) qmat[1,1]=(2*dy**2-dz**2-dx**2)*(1-1j*k*rr) qmat[2,2]=(2*dz**2-dx**2-dy**2)*(1-1j*k*rr) qmat[0,0]=qmat[0,0]+(-k**2*dx**2*rr**2) qmat[1,1]=qmat[1,1]+(-k**2*dy**2*rr**2) qmat[2,2]=qmat[2,2]+(-k**2*dz**2*rr**2) qmat[0,1]=(3-k**2*rr**2-3*1j*k*rr)*(dx*dy) qmat[1,2]=(3-k**2*rr**2-3*1j*k*rr)*(dy*dz) qmat[2,0]=(3-k**2*rr**2-3*1j*k*rr)*(dz*dx) qmat[1,0]=qmat[0,1] qmat[2,1]=qmat[1,2] qmat[0,2]=qmat[2,0] fout=np.exp(1j*k*rr)/rr**5/k**2 fvec = fout*np.dot(qmat,strength) evec = evec + fvec return evec def green3m(x,y,z,source,strength,k): # magnetic field corresponding to dyadic green's function # due to monochromatic electric dipole located at "source". # "strength" is the the intensity of the dipole. # H = curl((I + Hess)(exp(ikr)/r) dot (strength)) = # strength \cross \grad (exp(ikr)/r) # dx = x - source[0] dy = y - source[1] dz = z - source[2] rr = np.sqrt(dx**2 + dy**2 + dz**2) fout=(1-1j*k*rr)*np.exp(1j*k*rr)/rr**3 fvec = np.zeros(3,dtype=np.complex128) fvec[0] = fout*dx fvec[1] = fout*dy fvec[2] = fout*dz hvec = np.cross(strength,fvec) return hvec def dipole3e(x,y,z,source,strength,k): # # evalaute electric and magnetic field due # to monochromatic electric dipole located at "source" # with intensity "strength" evec = green3e(x,y,z,source,strength,k) evec = evec*1j*k hvec = green3m(x,y,z,source,strength,k) return evec,hvec def dipole3m(x,y,z,source,strength,k): # # evalaute electric and magnetic field due # to monochromatic magnetic dipole located at "source" # with intensity "strength" evec = green3m(x,y,z,source,strength,k) hvec = green3e(x,y,z,source,strength,k) hvec = -hvec*1j*k return evec,hvec def dipole3eall(x,y,z,sources,strengths,k): ns = len(strengths) evec = np.zeros(3,dtype=np.complex128) hvec = np.zeros(3,dtype=np.complex128) for i in range(ns): evect,hvect = dipole3e(x,y,z,sources[i],strengths[i],k) evec = evec + evect hvec = hvec + hvect nodes = density_discr.nodes().with_queue(queue).get() source = [0.01,-0.03,0.02] # source = cl.array.to_device(queue,np.zeros(3)) # source[0] = 0.01 # source[1] =-0.03 # source[2] = 0.02 strength = np.ones(3) # evec = cl.array.to_device(queue,np.zeros((3,len(nodes[0])),dtype=np.complex128)) # hvec = cl.array.to_device(queue,np.zeros((3,len(nodes[0])),dtype=np.complex128)) evec = np.zeros((3,len(nodes[0])),dtype=np.complex128) hvec = np.zeros((3,len(nodes[0])),dtype=np.complex128) for i in range(len(nodes[0])): evec[:,i],hvec[:,i] = dipole3e(nodes[0][i],nodes[1][i],nodes[2][i],source,strength,k) print(np.shape(hvec)) print(type(evec)) print(type(hvec)) evec = cl.array.to_device(queue,evec) hvec = cl.array.to_device(queue,hvec) bvp_rhs = bind(qbx, sym_rhs)(queue,Einc=evec,Hinc=hvec) print(np.shape(bvp_rhs)) print(type(bvp_rhs)) # print(bvp_rhs) 1/-1 bound_op = bind(qbx, sym_operator) from pytential.solve import gmres if 0: gmres_result = gmres( bound_op.scipy_op(queue, "sigma", dtype=np.complex128, k=k), bvp_rhs, tol=1e-8, progress=True, stall_iterations=0, hard_failure=True) sigma = gmres_result.solution fld_at_tgt = bind((qbx, PointsTarget(tgt_points)), sym_repr)(queue, sigma=bvp_rhs,k=k) fld_at_tgt = np.array([ fi.get() for fi in fld_at_tgt ]) print(fld_at_tgt) 1/0 # }}} #mlab.figure(bgcolor=(1, 1, 1)) if 1: from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(queue, density_discr, target_order) bdry_normals = bind(density_discr, sym.normal(3))(queue)\ .as_vector(dtype=object) bdry_vis.write_vtk_file("source.vtu", [ ("sigma", sigma), ("bdry_normals", bdry_normals), ]) fplot = FieldPlotter(bbox_center, extent=2*bbox_size, npoints=(150, 150, 1)) qbx_tgt_tol = qbx.copy(target_association_tolerance=0.1) from pytential.target import PointsTarget from pytential.qbx import QBXTargetAssociationFailedException rho_sym = sym.var("rho") try: fld_in_vol = bind( (qbx_tgt_tol, PointsTarget(fplot.points)), sym.make_obj_array([ sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None), sym.d_dx(3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), sym.d_dy(3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), sym.d_dz(3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), ]) )(queue, jt=jt, rho=rho, k=k) except QBXTargetAssociationFailedException as e: fplot.write_vtk_file( "failed-targets.vts", [ ("failed_targets", e.failed_target_flags.get(queue)) ]) raise fld_in_vol = sym.make_obj_array( [fiv.get() for fiv in fld_in_vol]) #fplot.show_scalar_in_mayavi(fld_in_vol.real, max_val=5) fplot.write_vtk_file( "potential.vts", [ ("potential", fld_in_vol[0]), ("grad", fld_in_vol[1:]), ] )
def test_3d_jump_relations(ctx_factory, relation, visualize=False): # logging.basicConfig(level=logging.INFO) cl_ctx = ctx_factory() queue = cl.CommandQueue(cl_ctx) if relation == "div_s": target_order = 3 else: target_order = 4 qbx_order = target_order from pytools.convergence import EOCRecorder eoc_rec = EOCRecorder() for nel_factor in [6, 10, 14]: from meshmode.mesh.generation import generate_torus mesh = generate_torus( 5, 2, order=target_order, n_outer=2*nel_factor, n_inner=nel_factor) from meshmode.discretization import Discretization from meshmode.discretization.poly_element import \ InterpolatoryQuadratureSimplexGroupFactory pre_discr = Discretization( cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(3)) from pytential.qbx import QBXLayerPotentialSource qbx, _ = QBXLayerPotentialSource( pre_discr, fine_order=4*target_order, qbx_order=qbx_order, fmm_order=qbx_order + 5, fmm_backend="fmmlib" ).with_refinement() from sumpy.kernel import LaplaceKernel knl = LaplaceKernel(3) def nxcurlS(qbx_forced_limit): return sym.n_cross(sym.curl(sym.S( knl, sym.cse(sym.tangential_to_xyz(density_sym), "jxyz"), qbx_forced_limit=qbx_forced_limit))) x, y, z = qbx.density_discr.nodes().with_queue(queue) m = cl.clmath if relation == "nxcurls": density_sym = sym.make_sym_vector("density", 2) jump_identity_sym = ( nxcurlS(+1) - (nxcurlS("avg") + 0.5*sym.tangential_to_xyz(density_sym))) # The tangential coordinate system is element-local, so we can't just # conjure up some globally smooth functions, interpret their values # in the tangential coordinate system, and be done. Instead, generate # an XYZ function and project it. density = bind( qbx, sym.xyz_to_tangential(sym.make_sym_vector("jxyz", 3)))( queue, jxyz=sym.make_obj_array([ m.cos(0.5*x) * m.cos(0.5*y) * m.cos(0.5*z), m.sin(0.5*x) * m.cos(0.5*y) * m.sin(0.5*z), m.sin(0.5*x) * m.cos(0.5*y) * m.cos(0.5*z), ])) elif relation == "sp": density = m.cos(2*x) * m.cos(2*y) * m.cos(z) density_sym = sym.var("density") jump_identity_sym = ( sym.Sp(knl, density_sym, qbx_forced_limit=+1) - (sym.Sp(knl, density_sym, qbx_forced_limit="avg") - 0.5*density_sym)) elif relation == "div_s": density = m.cos(2*x) * m.cos(2*y) * m.cos(z) density_sym = sym.var("density") jump_identity_sym = ( sym.div(sym.S(knl, sym.normal(3).as_vector()*density_sym, qbx_forced_limit="avg")) + sym.D(knl, density_sym, qbx_forced_limit="avg")) else: raise ValueError("unexpected value of 'relation': %s" % relation) bound_jump_identity = bind(qbx, jump_identity_sym) jump_identity = bound_jump_identity(queue, density=density) err = ( norm(qbx, queue, jump_identity, np.inf) / norm(qbx, queue, density, np.inf)) print("ERROR", qbx.h_max, err) eoc_rec.add_data_point(qbx.h_max, err) # {{{ visualization if visualize and relation == "nxcurls": nxcurlS_ext = bind(qbx, nxcurlS(+1))(queue, density=density) nxcurlS_avg = bind(qbx, nxcurlS("avg"))(queue, density=density) jtxyz = bind(qbx, sym.tangential_to_xyz(density_sym))( queue, density=density) from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(queue, qbx.density_discr, target_order+3) bdry_normals = bind(qbx, sym.normal(3))(queue)\ .as_vector(dtype=object) bdry_vis.write_vtk_file("source-%s.vtu" % nel_factor, [ ("jt", jtxyz), ("nxcurlS_ext", nxcurlS_ext), ("nxcurlS_avg", nxcurlS_avg), ("bdry_normals", bdry_normals), ]) if visualize and relation == "sp": sp_ext = bind(qbx, sym.Sp(knl, density_sym, qbx_forced_limit=+1))( queue, density=density) sp_avg = bind(qbx, sym.Sp(knl, density_sym, qbx_forced_limit="avg"))( queue, density=density) from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(queue, qbx.density_discr, target_order+3) bdry_normals = bind(qbx, sym.normal(3))(queue)\ .as_vector(dtype=object) bdry_vis.write_vtk_file("source-%s.vtu" % nel_factor, [ ("density", density), ("sp_ext", sp_ext), ("sp_avg", sp_avg), ("bdry_normals", bdry_normals), ]) # }}} print(eoc_rec) assert eoc_rec.order_estimate() >= qbx_order - 1.5
def test_3d_jump_relations(ctx_factory, relation, visualize=False): # logging.basicConfig(level=logging.INFO) cl_ctx = ctx_factory() queue = cl.CommandQueue(cl_ctx) actx = PyOpenCLArrayContext(queue) if relation == "div_s": target_order = 3 else: target_order = 4 qbx_order = target_order from pytools.convergence import EOCRecorder eoc_rec = EOCRecorder() for nel_factor in [6, 10, 14]: from meshmode.mesh.generation import generate_torus mesh = generate_torus( 5, 2, order=target_order, n_major=2*nel_factor, n_minor=nel_factor) from meshmode.discretization import Discretization from meshmode.discretization.poly_element import \ InterpolatoryQuadratureSimplexGroupFactory pre_discr = Discretization( actx, mesh, InterpolatoryQuadratureSimplexGroupFactory(3)) from pytential.qbx import QBXLayerPotentialSource qbx = QBXLayerPotentialSource( pre_discr, fine_order=4*target_order, qbx_order=qbx_order, fmm_order=qbx_order + 5, fmm_backend="fmmlib" ) places = GeometryCollection(qbx) density_discr = places.get_discretization(places.auto_source.geometry) from sumpy.kernel import LaplaceKernel knl = LaplaceKernel(3) def nxcurlS(qbx_forced_limit): return sym.n_cross(sym.curl(sym.S( knl, sym.cse(sym.tangential_to_xyz(density_sym), "jxyz"), qbx_forced_limit=qbx_forced_limit))) from meshmode.dof_array import thaw x, y, z = thaw(actx, density_discr.nodes()) m = actx.np if relation == "nxcurls": density_sym = sym.make_sym_vector("density", 2) jump_identity_sym = ( nxcurlS(+1) - (nxcurlS("avg") + 0.5*sym.tangential_to_xyz(density_sym))) # The tangential coordinate system is element-local, so we can't just # conjure up some globally smooth functions, interpret their values # in the tangential coordinate system, and be done. Instead, generate # an XYZ function and project it. density = bind(places, sym.xyz_to_tangential(sym.make_sym_vector("jxyz", 3)))( actx, jxyz=sym.make_obj_array([ m.cos(0.5*x) * m.cos(0.5*y) * m.cos(0.5*z), m.sin(0.5*x) * m.cos(0.5*y) * m.sin(0.5*z), m.sin(0.5*x) * m.cos(0.5*y) * m.cos(0.5*z), ])) elif relation == "sp": density = m.cos(2*x) * m.cos(2*y) * m.cos(z) density_sym = sym.var("density") jump_identity_sym = ( sym.Sp(knl, density_sym, qbx_forced_limit=+1) - (sym.Sp(knl, density_sym, qbx_forced_limit="avg") - 0.5*density_sym)) elif relation == "div_s": density = m.cos(2*x) * m.cos(2*y) * m.cos(z) density_sym = sym.var("density") jump_identity_sym = ( sym.div(sym.S(knl, sym.normal(3).as_vector()*density_sym, qbx_forced_limit="avg")) + sym.D(knl, density_sym, qbx_forced_limit="avg")) else: raise ValueError("unexpected value of 'relation': %s" % relation) bound_jump_identity = bind(places, jump_identity_sym) jump_identity = bound_jump_identity(actx, density=density) h_max = bind(places, sym.h_max(qbx.ambient_dim))(actx) err = ( norm(density_discr, jump_identity, np.inf) / norm(density_discr, density, np.inf)) print("ERROR", h_max, err) eoc_rec.add_data_point(h_max, err) # {{{ visualization if visualize and relation == "nxcurls": nxcurlS_ext = bind(places, nxcurlS(+1))(actx, density=density) nxcurlS_avg = bind(places, nxcurlS("avg"))(actx, density=density) jtxyz = bind(places, sym.tangential_to_xyz(density_sym))( actx, density=density) from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(actx, qbx.density_discr, target_order+3) bdry_normals = bind(places, sym.normal(3))(actx)\ .as_vector(dtype=object) bdry_vis.write_vtk_file("source-%s.vtu" % nel_factor, [ ("jt", jtxyz), ("nxcurlS_ext", nxcurlS_ext), ("nxcurlS_avg", nxcurlS_avg), ("bdry_normals", bdry_normals), ]) if visualize and relation == "sp": op = sym.Sp(knl, density_sym, qbx_forced_limit=+1) sp_ext = bind(places, op)(actx, density=density) op = sym.Sp(knl, density_sym, qbx_forced_limit="avg") sp_avg = bind(places, op)(actx, density=density) from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(actx, qbx.density_discr, target_order+3) bdry_normals = bind(places, sym.normal(3))(actx).as_vector(dtype=object) bdry_vis.write_vtk_file("source-%s.vtu" % nel_factor, [ ("density", density), ("sp_ext", sp_ext), ("sp_avg", sp_avg), ("bdry_normals", bdry_normals), ]) # }}} print(eoc_rec) assert eoc_rec.order_estimate() >= qbx_order - 1.5
def main(): # cl.array.to_device(queue, numpy_array) from meshmode.mesh.io import generate_gmsh, FileSource mesh = generate_gmsh( FileSource("ellipsoid.step"), 2, order=2, other_options=["-string", "Mesh.CharacteristicLengthMax = %g;" % h]) from meshmode.mesh.processing import perform_flips # Flip elements--gmsh generates inside-out geometry. mesh = perform_flips(mesh, np.ones(mesh.nelements)) print("%d elements" % mesh.nelements) from meshmode.mesh.processing import find_bounding_box bbox_min, bbox_max = find_bounding_box(mesh) bbox_center = 0.5 * (bbox_min + bbox_max) bbox_size = max(bbox_max - bbox_min) / 2 logger.info("%d elements" % mesh.nelements) from pytential.qbx import QBXLayerPotentialSource from meshmode.discretization import Discretization from meshmode.discretization.poly_element import \ InterpolatoryQuadratureSimplexGroupFactory density_discr = Discretization( cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(target_order)) qbx = QBXLayerPotentialSource(density_discr, 4 * target_order, qbx_order, fmm_order=qbx_order + 10, fmm_backend="fmmlib") from pytential.symbolic.pde.maxwell import MuellerAugmentedMFIEOperator pde_op = MuellerAugmentedMFIEOperator( omega=0.4, epss=[1.4, 1.0], mus=[1.2, 1.0], ) from pytential import bind, sym unk = pde_op.make_unknown("sigma") sym_operator = pde_op.operator(unk) sym_rhs = pde_op.rhs(sym.make_sym_vector("Einc", 3), sym.make_sym_vector("Hinc", 3)) sym_repr = pde_op.representation(0, unk) if 1: expr = sym_repr print(sym.pretty(expr)) print("#" * 80) from pytential.target import PointsTarget tgt_points = np.zeros((3, 1)) tgt_points[0, 0] = 100 tgt_points[1, 0] = -200 tgt_points[2, 0] = 300 bound_op = bind((qbx, PointsTarget(tgt_points)), expr) print(bound_op.code) if 1: def green3e(x, y, z, source, strength, k): # electric field corresponding to dyadic green's function # due to monochromatic electric dipole located at "source". # "strength" is the the intensity of the dipole. # E = (I + Hess)(exp(ikr)/r) dot (strength) # dx = x - source[0] dy = y - source[1] dz = z - source[2] rr = np.sqrt(dx**2 + dy**2 + dz**2) fout = np.exp(1j * k * rr) / rr evec = fout * strength qmat = np.zeros((3, 3), dtype=np.complex128) qmat[0, 0] = (2 * dx**2 - dy**2 - dz**2) * (1 - 1j * k * rr) qmat[1, 1] = (2 * dy**2 - dz**2 - dx**2) * (1 - 1j * k * rr) qmat[2, 2] = (2 * dz**2 - dx**2 - dy**2) * (1 - 1j * k * rr) qmat[0, 0] = qmat[0, 0] + (-k**2 * dx**2 * rr**2) qmat[1, 1] = qmat[1, 1] + (-k**2 * dy**2 * rr**2) qmat[2, 2] = qmat[2, 2] + (-k**2 * dz**2 * rr**2) qmat[0, 1] = (3 - k**2 * rr**2 - 3 * 1j * k * rr) * (dx * dy) qmat[1, 2] = (3 - k**2 * rr**2 - 3 * 1j * k * rr) * (dy * dz) qmat[2, 0] = (3 - k**2 * rr**2 - 3 * 1j * k * rr) * (dz * dx) qmat[1, 0] = qmat[0, 1] qmat[2, 1] = qmat[1, 2] qmat[0, 2] = qmat[2, 0] fout = np.exp(1j * k * rr) / rr**5 / k**2 fvec = fout * np.dot(qmat, strength) evec = evec + fvec return evec def green3m(x, y, z, source, strength, k): # magnetic field corresponding to dyadic green's function # due to monochromatic electric dipole located at "source". # "strength" is the the intensity of the dipole. # H = curl((I + Hess)(exp(ikr)/r) dot (strength)) = # strength \cross \grad (exp(ikr)/r) # dx = x - source[0] dy = y - source[1] dz = z - source[2] rr = np.sqrt(dx**2 + dy**2 + dz**2) fout = (1 - 1j * k * rr) * np.exp(1j * k * rr) / rr**3 fvec = np.zeros(3, dtype=np.complex128) fvec[0] = fout * dx fvec[1] = fout * dy fvec[2] = fout * dz hvec = np.cross(strength, fvec) return hvec def dipole3e(x, y, z, source, strength, k): # # evalaute electric and magnetic field due # to monochromatic electric dipole located at "source" # with intensity "strength" evec = green3e(x, y, z, source, strength, k) evec = evec * 1j * k hvec = green3m(x, y, z, source, strength, k) return evec, hvec def dipole3m(x, y, z, source, strength, k): # # evalaute electric and magnetic field due # to monochromatic magnetic dipole located at "source" # with intensity "strength" evec = green3m(x, y, z, source, strength, k) hvec = green3e(x, y, z, source, strength, k) hvec = -hvec * 1j * k return evec, hvec def dipole3eall(x, y, z, sources, strengths, k): ns = len(strengths) evec = np.zeros(3, dtype=np.complex128) hvec = np.zeros(3, dtype=np.complex128) for i in range(ns): evect, hvect = dipole3e(x, y, z, sources[i], strengths[i], k) evec = evec + evect hvec = hvec + hvect nodes = density_discr.nodes().with_queue(queue).get() source = [0.01, -0.03, 0.02] # source = cl.array.to_device(queue,np.zeros(3)) # source[0] = 0.01 # source[1] =-0.03 # source[2] = 0.02 strength = np.ones(3) # evec = cl.array.to_device(queue,np.zeros((3,len(nodes[0])),dtype=np.complex128)) # hvec = cl.array.to_device(queue,np.zeros((3,len(nodes[0])),dtype=np.complex128)) evec = np.zeros((3, len(nodes[0])), dtype=np.complex128) hvec = np.zeros((3, len(nodes[0])), dtype=np.complex128) for i in range(len(nodes[0])): evec[:, i], hvec[:, i] = dipole3e(nodes[0][i], nodes[1][i], nodes[2][i], source, strength, k) print(np.shape(hvec)) print(type(evec)) print(type(hvec)) evec = cl.array.to_device(queue, evec) hvec = cl.array.to_device(queue, hvec) bvp_rhs = bind(qbx, sym_rhs)(queue, Einc=evec, Hinc=hvec) print(np.shape(bvp_rhs)) print(type(bvp_rhs)) # print(bvp_rhs) 1 / -1 bound_op = bind(qbx, sym_operator) from pytential.solve import gmres if 0: gmres_result = gmres(bound_op.scipy_op(queue, "sigma", dtype=np.complex128, k=k), bvp_rhs, tol=1e-8, progress=True, stall_iterations=0, hard_failure=True) sigma = gmres_result.solution fld_at_tgt = bind((qbx, PointsTarget(tgt_points)), sym_repr)(queue, sigma=bvp_rhs, k=k) fld_at_tgt = np.array([fi.get() for fi in fld_at_tgt]) print(fld_at_tgt) 1 / 0 # }}} #mlab.figure(bgcolor=(1, 1, 1)) if 1: from meshmode.discretization.visualization import make_visualizer bdry_vis = make_visualizer(queue, density_discr, target_order) bdry_normals = bind(density_discr, sym.normal(3))(queue)\ .as_vector(dtype=object) bdry_vis.write_vtk_file("source.vtu", [ ("sigma", sigma), ("bdry_normals", bdry_normals), ]) fplot = FieldPlotter(bbox_center, extent=2 * bbox_size, npoints=(150, 150, 1)) qbx_tgt_tol = qbx.copy(target_association_tolerance=0.1) from pytential.target import PointsTarget from pytential.qbx import QBXTargetAssociationFailedException rho_sym = sym.var("rho") try: fld_in_vol = bind((qbx_tgt_tol, PointsTarget(fplot.points)), sym.make_obj_array([ sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None), sym.d_dx( 3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), sym.d_dy( 3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), sym.d_dz( 3, sym.S(pde_op.kernel, rho_sym, k=sym.var("k"), qbx_forced_limit=None)), ]))(queue, jt=jt, rho=rho, k=k) except QBXTargetAssociationFailedException as e: fplot.write_vtk_file( "failed-targets.vts", [("failed_targets", e.failed_target_flags.get(queue))]) raise fld_in_vol = sym.make_obj_array([fiv.get() for fiv in fld_in_vol]) #fplot.show_scalar_in_mayavi(fld_in_vol.real, max_val=5) fplot.write_vtk_file("potential.vts", [ ("potential", fld_in_vol[0]), ("grad", fld_in_vol[1:]), ])
def test_3d_jump_relations(actx_factory, relation, visualize=False): # logging.basicConfig(level=logging.INFO) actx = actx_factory() if relation == "div_s": target_order = 3 else: target_order = 4 qbx_order = target_order if relation == "sp": resolutions = [10, 14, 18] else: resolutions = [6, 10, 14] from pytools.convergence import EOCRecorder eoc_rec = EOCRecorder() for nel_factor in resolutions: from meshmode.mesh.generation import generate_torus mesh = generate_torus( 5, 2, n_major=2 * nel_factor, n_minor=nel_factor, order=target_order, ) from meshmode.discretization import Discretization from meshmode.discretization.poly_element import \ InterpolatoryQuadratureSimplexGroupFactory pre_density_discr = Discretization( actx, mesh, InterpolatoryQuadratureSimplexGroupFactory(target_order)) from pytential.qbx import QBXLayerPotentialSource qbx = QBXLayerPotentialSource(pre_density_discr, fine_order=5 * target_order, qbx_order=qbx_order, fmm_order=qbx_order + 5, fmm_backend="fmmlib") places = GeometryCollection(qbx) density_discr = places.get_discretization(places.auto_source.geometry) from sumpy.kernel import LaplaceKernel knl = LaplaceKernel(places.ambient_dim) def nxcurlS(qbx_forced_limit): sigma_sym = sym.cse(sym.tangential_to_xyz(density_sym), "jxyz") return sym.n_cross( sym.curl( sym.S(knl, sigma_sym, qbx_forced_limit=qbx_forced_limit))) x, y, z = thaw(density_discr.nodes(), actx) if relation == "nxcurls": density_sym = sym.make_sym_vector("density", 2) jump_identity_sym = (nxcurlS(+1) - nxcurlS("avg") - 0.5 * sym.tangential_to_xyz(density_sym)) # The tangential coordinate system is element-local, so we can't just # conjure up some globally smooth functions, interpret their values # in the tangential coordinate system, and be done. Instead, generate # an XYZ function and project it. jxyz = sym.make_obj_array([ actx.np.cos(0.5 * x) * actx.np.cos(0.5 * y) * actx.np.cos(0.5 * z), actx.np.sin(0.5 * x) * actx.np.cos(0.5 * y) * actx.np.sin(0.5 * z), actx.np.sin(0.5 * x) * actx.np.cos(0.5 * y) * actx.np.cos(0.5 * z), ]) density = bind( places, sym.xyz_to_tangential(sym.make_sym_vector("jxyz", 3)))(actx, jxyz=jxyz) elif relation == "sp": density_sym = sym.var("density") jump_identity_sym = ( 0.5 * density_sym + sym.Sp(knl, density_sym, qbx_forced_limit=+1) - sym.Sp(knl, density_sym, qbx_forced_limit="avg")) density = actx.np.cos(2 * x) * actx.np.cos(2 * y) * actx.np.cos(z) elif relation == "div_s": density_sym = sym.var("density") sigma_sym = sym.normal( places.ambient_dim).as_vector() * density_sym jump_identity_sym = ( sym.div(sym.S(knl, sigma_sym, qbx_forced_limit="avg")) + sym.D(knl, density_sym, qbx_forced_limit="avg")) density = actx.np.cos(2 * x) * actx.np.cos(2 * y) * actx.np.cos(z) else: raise ValueError(f"unexpected value of 'relation': '{relation}'") bound_jump_identity = bind(places, jump_identity_sym) jump_identity = bound_jump_identity(actx, density=density) h_max = actx.to_numpy( bind(places, sym.h_max(places.ambient_dim))(actx)) err = actx.to_numpy( norm(density_discr, jump_identity, np.inf) / norm(density_discr, density, np.inf)) eoc_rec.add_data_point(h_max, err) logging.info("error: nel %d h_max %.5e %.5e", nel_factor, h_max, err) # {{{ visualization if not visualize: continue from meshmode.discretization.visualization import make_visualizer vis = make_visualizer(actx, density_discr, target_order) normals = bind(places, sym.normal(places.ambient_dim).as_vector())(actx) error = actx.np.log10(actx.np.abs(jump_identity) + 1.0e-15) if relation == "nxcurls": nxcurlS_ext = bind(places, nxcurlS(+1))(actx, density=density) nxcurlS_avg = bind(places, nxcurlS("avg"))(actx, density=density) jtxyz = bind(places, sym.tangential_to_xyz(density_sym))(actx, density=density) vis.write_vtk_file(f"source-nxcurls-{nel_factor:03d}.vtu", [ ("jt", jtxyz), ("nxcurlS_ext", nxcurlS_ext), ("nxcurlS_avg", nxcurlS_avg), ("bdry_normals", normals), ("error", error), ]) elif relation == "sp": op = sym.Sp(knl, density_sym, qbx_forced_limit=+1) sp_ext = bind(places, op)(actx, density=density) op = sym.Sp(knl, density_sym, qbx_forced_limit="avg") sp_avg = bind(places, op)(actx, density=density) vis.write_vtk_file(f"source-sp-{nel_factor:03d}.vtu", [ ("density", density), ("sp_ext", sp_ext), ("sp_avg", sp_avg), ("bdry_normals", normals), ("error", error), ]) elif relation == "div_s": vis.write_vtk_file(f"source-div-{nel_factor:03d}.vtu", [ ("density", density), ("bdry_normals", normals), ("error", error), ]) # }}} logger.info("\n%s", str(eoc_rec)) assert eoc_rec.order_estimate() >= qbx_order - 1.5
def main(): import logging logging.basicConfig(level=logging.INFO) cl_ctx = cl.create_some_context() queue = cl.CommandQueue(cl_ctx) from meshmode.mesh.generation import ellipse, make_curve_mesh from functools import partial mesh = make_curve_mesh( partial(ellipse, 2), np.linspace(0, 1, nelements+1), mesh_order) pre_density_discr = Discretization( cl_ctx, mesh, InterpolatoryQuadratureSimplexGroupFactory(bdry_quad_order)) from pytential.qbx import ( QBXLayerPotentialSource, QBXTargetAssociationFailedException) qbx, _ = QBXLayerPotentialSource( pre_density_discr, fine_order=bdry_ovsmp_quad_order, qbx_order=qbx_order, fmm_order=fmm_order, expansion_disks_in_tree_have_extent=True, ).with_refinement() density_discr = qbx.density_discr from pytential.symbolic.pde.cahn_hilliard import CahnHilliardOperator chop = CahnHilliardOperator( # FIXME: Constants? lambda1=1.5, lambda2=1.25, c=1) unk = chop.make_unknown("sigma") bound_op = bind(qbx, chop.operator(unk)) # {{{ fix rhs and solve nodes = density_discr.nodes().with_queue(queue) def g(xvec): x, y = xvec return cl.clmath.atan2(y, x) bc = sym.make_obj_array([ # FIXME: Realistic BC g(nodes), -g(nodes), ]) from pytential.solve import gmres gmres_result = gmres( bound_op.scipy_op(queue, "sigma", dtype=np.complex128), bc, tol=1e-8, progress=True, stall_iterations=0, hard_failure=True) # }}} # {{{ postprocess/visualize sigma = gmres_result.solution from sumpy.visualization import FieldPlotter fplot = FieldPlotter(np.zeros(2), extent=5, npoints=500) targets = cl.array.to_device(queue, fplot.points) qbx_stick_out = qbx.copy(target_association_tolerance=0.05) indicator_qbx = qbx_stick_out.copy(qbx_order=2) from sumpy.kernel import LaplaceKernel ones_density = density_discr.zeros(queue) ones_density.fill(1) indicator = bind( (indicator_qbx, PointsTarget(targets)), sym.D(LaplaceKernel(2), sym.var("sigma")))( queue, sigma=ones_density).get() try: fld_in_vol = bind( (qbx_stick_out, PointsTarget(targets)), chop.representation(unk))(queue, sigma=sigma).get() except QBXTargetAssociationFailedException as e: fplot.write_vtk_file( "failed-targets.vts", [ ("failed", e.failed_target_flags.get(queue)) ] ) raise #fplot.show_scalar_in_mayavi(fld_in_vol.real, max_val=5) fplot.write_vtk_file( "potential.vts", [ ("potential", fld_in_vol), ("indicator", indicator), ] )