示例#1
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    def show_mesh(self, p=2, plot=True):

        mf = MeshFactory()

        mesh = mf.boxmesh2d([0, 1, 0, 1], nx=2, ny=2, meshtype='tri')
        node = mesh.entity('node')
        cell = mesh.entity('cell')

        ltmesh = LagrangeTriangleMesh(node, cell, p=p)
        NN = ltmesh.number_of_nodes()

        mesh.ds.edge = ltmesh.lds.edge
        mesh.ds.edge2cell = ltmesh.lds.edge2cell

        node = ltmesh.entity('node')
        #ltmesh.print()

        if plot:
            fig = plt.figure()
            axes = fig.gca()
            mesh.add_plot(axes)
            mesh.find_node(axes, node=node, showindex=True, fontsize=28)
            mesh.find_edge(axes, showindex=True)
            mesh.find_cell(axes, showindex=True)
            plt.show()
示例#2
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    def save_mesh(self, p=2, fname='test.vtu'):
        mf = MeshFactory()

        mesh = mf.boxmesh2d([0, 1, 0, 1], nx=2, ny=2, meshtype='tri')
        node = mesh.entity('node')
        cell = mesh.entity('cell')

        mesh = LagrangeTriangleMesh(node, cell, p=p)
        mesh.to_vtk(fname=fname)
示例#3
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    def init_mesh(self, n=0, h=0.005, nh=100, p=1):
        fname = 'initial/file1.vtu'
        data = meshio.read(fname)
        node = data.points
        cell = data.cells[0][1]

        mesh = LagrangeTriangleMesh(node * 500, cell, p=p)
        mesh.uniform_refine(n)
        mesh = LagrangeWedgeMesh(mesh, h, nh, p=p)

        self.mesh = mesh
        self.p = p
        return mesh
示例#4
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def test_lagrange_triangle_mesh(p):
    from fealpy.mesh import LagrangeTriangleMesh
    node = np.array(
        [
            (0.0, 0.0),  # 0 号点
            (1.0, 0.0),  # 1 号点
            (1.0, 1.0),  # 2 号点
            (0.0, 1.0),  # 3 号点
        ],
        dtype=np.float64)
    cell = np.array(
        [
            (1, 2, 0),  # 0 号单元
            (3, 0, 2),  # 1 号单元
        ],
        dtype=np.int_)

    mesh = LagrangeTriangleMesh(node, cell, p=p)

    cell2node = mesh.ds.cell_to_node()
    cell2edge = mesh.ds.cell_to_edge()
    cell2cell = mesh.ds.cell_to_cell()

    edge2node = mesh.ds.edge_to_node()
    edge2edge = mesh.ds.edge_to_edge()
    edge2cell = mesh.ds.edge_to_cell()

    node2node = mesh.ds.node_to_node()
    node2edge = mesh.ds.node_to_edge()
    node2cell = mesh.ds.node_to_cell()
    def interpolation(self, p=2, n=1, fname='surface.vtu'):
        from fealpy.geometry import SphereSurface
        from fealpy.pde.surface_poisson_model_3d import SphereSinSinSinData

        pde = SphereSinSinSinData()
        surface = pde.domain()
        mesh = pde.init_mesh(n=n)

        node = mesh.entity('node')
        cell = mesh.entity('cell')

        mesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
        space = ParametricLagrangeFiniteElementSpace(mesh, p=p)

        uI = space.interpolation(pde.solution)
        mesh.nodedata['uI'] = uI[:]
        error0 = space.integralalg.error(pde.solution, uI.value)
        error1 = space.integralalg.error(pde.gradient, uI.grad_value)
        print(error0, error1)
        mesh.to_vtk(fname=fname)
示例#6
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    def surface_area(self, p=2):
        from fealpy.geometry import SphereSurface

        surface = SphereSurface()
        mesh = surface.init_mesh()
        e = 0
        maxit = 5
        for i in range(maxit):
            node = mesh.entity('node')
            cell = mesh.entity('cell')

            lmesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
            NC = lmesh.number_of_cells()
            a = lmesh.cell_area()
            a = sum(a)
            a_e = (4 * np.pi)
            e_new = abs(a - a_e)
            order = np.log2(e / e_new)
            e = e_new
            print("e:", e)
            print("0:", order)
            if i < maxit - 1:
                mesh.uniform_refine(surface=surface)
def opt_mesh(mesh):
    p = mesh.p
    surface = mesh.surface
    NCN = mesh.number_of_corner_nodes()
    node = mesh.entity('node')[:NCN].copy()
    cell = mesh.entity('cell')[:, [0, -p - 1, -1]]
    tmesh = TriangleMesh(node, cell)
    alg = SurfaceTriangleMeshOptAlg(surface, tmesh)
    alg.run(maxit=10)

    node = alg.mesh.entity('node')
    cell = alg.mesh.entity('cell')
    mesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
    return mesh
示例#8
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    def surface_mesh(self, p=2, fname='surface.vtu'):
        from fealpy.geometry import SphereSurface, EllipsoidSurface, SphereSurfaceTest

        surface = SphereSurface()
        #surface = SphereSurfaceTest()
        #surface = EllipsoidSurface()
        #surface = ScaledSurface(surface,scale=[9,3,1])
        mesh = surface.init_mesh()

        node = mesh.entity('node')
        cell = mesh.entity('cell')

        lmesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
        NC = lmesh.number_of_cells()
        a = lmesh.cell_area()
        lmesh.to_vtk(fname=fname)
示例#9
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 def init_mesh(self, meshtype='tri', returnnc=False, p=None):
     if meshtype == 'tri':
         t = (np.sqrt(5) - 1)/2
         node = np.array([
             [ 0, 1, t],
             [ 0, 1,-t],
             [ 1, t, 0],
             [ 1,-t, 0],
             [ 0,-1,-t],
             [ 0,-1, t],
             [ t, 0, 1],
             [-t, 0, 1],
             [ t, 0,-1],
             [-t, 0,-1],
             [-1, t, 0],
             [-1,-t, 0]], dtype=np.float64)
         cell = np.array([
             [6, 2, 0],
             [3, 2, 6],
             [5, 3, 6],
             [5, 6, 7],
             [6, 0, 7],
             [3, 8, 2],
             [2, 8, 1],
             [2, 1, 0],
             [0, 1,10],
             [1, 9,10],
             [8, 9, 1],
             [4, 8, 3],
             [4, 3, 5],
             [4, 5,11],
             [7,10,11],
             [0,10, 7],
             [4,11, 9],
             [8, 4, 9],
             [5, 7,11],
             [10,9,11]], dtype=np.int)
         node, d = self.project(node)
         if returnnc:
             return node, cell
         else:
             if p is None:
                 from fealpy.mesh import TriangleMesh
                 return TriangleMesh(node, cell) 
             else:
                 from fealpy.mesh import LagrangeTriangleMesh
                 return LagrangeTriangleMesh(node, cell, p=p, surface=self) 
     elif meshtype == 'quad':
         node = np.array([
             (-1, -1, -1),
             (-1, -1, 1),
             (-1, 1, -1),
             (-1, 1, 1),
             (1, -1, -1),
             (1, -1, 1),
             (1, 1, -1),
             (1, 1, 1)], dtype=np.float64)
         cell = np.array([
             (0, 1, 4, 5),
             (6, 7, 2, 3),
             (2, 3, 0, 1),
             (4, 5, 6, 7),
             (1, 3, 5, 7),
             (2, 0, 6, 4)], dtype=np.int_)
         node, d = self.project(node)
         if returnnc:
             return node, cell
         else:
             if p is None:
                 from fealpy.mesh import QuadrangleMesh 
                 return QuadrangleMesh(node, cell) 
             else:
                 from fealpy.mesh import LagrangeQuadrangleMesh 
                 return LagrangeQuadrangleMesh(node, cell, p=p, surface=self) 
示例#10
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pde = PDE()
surface = pde.domain()
mesh = pde.init_mesh(n=n)

errorType = ['$|| u - u_h||_{\Omega,0}$'
             ]
errorMatrix = np.zeros((len(errorType), maxit), dtype=np.float)
NDof = np.zeros(maxit, dtype=np.float)

for i in range(maxit):
    print("The {}-th computation:".format(i))

    node = mesh.entity('node')
    cell = mesh.entity('cell')

    lmesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
    space = IsoLagrangeFiniteElementSpace(lmesh, p=p)
    NDof[i] = space.number_of_global_dofs()

    qf = lmesh.integrator(q=p+3, etype='cell')
    bcs, ws = qf.get_quadrature_points_and_weights()

    Jh = lmesh.jacobi_matrix(bcs)
    nh = np.cross(Jh[..., 0], Jh[..., 1], axis=-1)
    val = np.sqrt(np.sum(nh**2, axis=-1))
    nh[...,0] /=val
    nh[...,1] /=val
    nh[...,2] /=val

    bc = lmesh.bc_to_point(bcs)
    n = pde.normal(bc)
示例#11
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文件: Eplltic.py 项目: ymjyxw/fealpy
surface = pde.domain()
mesh = pde.init_mesh(n=n)

errorType = [
    '$|| u - u_h||_{\Omega,0}$', '$||\\nabla u - \\nabla u_h||_{\Omega, 0}$',
    '$|| u - u_I||_{\Omega,0}$', '$||\\nabla u - \\nabla u_I||_{\Omega, 0}$'
]
errorMatrix = np.zeros((len(errorType), maxit), dtype=np.float)
NDof = np.zeros(maxit, dtype=np.float)

for i in range(maxit):
    print("The {}-th computation:".format(i))

    node = mesh.entity('node')
    cell = mesh.entity('cell')
    lmesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
    space = IsoLagrangeFiniteElementSpace(lmesh, p=p)
    NDof[i] = space.number_of_global_dofs()
    print(NDof[i])

    uh = space.function()
    A = space.stiff_matrix()
    F = space.source_vector(pde.source)

    # 封闭曲面,设置其第 0 个插值节点的值为真解值
    bc = DirichletBC(space, pde.solution)
    A, F = bc.apply(A, F, uh, threshold=np.array([0]))
    uh[:] = spsolve(A, F).reshape(-1)

    uI = space.interpolation(pde.solution)
    errorMatrix[0, i] = space.integralalg.error(pde.solution,
示例#12
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pde = PDE()
surface = pde.domain()
mesh = pde.init_mesh(n=n)

errorType = ['$|| u - u_h||_{\Omega,0}$'
             ]
errorMatrix = np.zeros((len(errorType), maxit), dtype=np.float)
NDof = np.zeros(maxit, dtype=np.float)

for i in range(maxit):
    print("The {}-th computation:".format(i))

    node = mesh.entity('node')
    cell = mesh.entity('cell')

    lmesh = LagrangeTriangleMesh(node, cell, p=p, surface=surface)
    space = IsoLagrangeFiniteElementSpace(lmesh, p=p)
    NDof[i] = space.number_of_global_dofs()

    qf = lmesh.integrator(q=p+3, etype='cell')
    bcs, ws = qf.get_quadrature_points_and_weights()
    print('bcs', bcs.shape)
    gphi = lmesh.grad_shape_function(bcs, p=p) #(NQ,NC,ldof,TD)
    print('gphi', gphi.shape)
    Jh = lmesh.jacobi_matrix(bcs)
    print('Jh', Jh.shape)
    bc = lmesh.bc_to_point(bcs)
    print('bc', bc.shape)
    val = np.sum(bc, axis =-1)
    print('val', val.shape)
    val1 = (Jh.T/val.T).T
示例#13
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#import scipy.io as sio

from fealpy.mesh import LagrangeTriangleMesh, MeshFactory, LagrangeWedgeMesh
from fealpy.writer import MeshWriter

#p = int(sys.argv[1])
#n = int(sys.argv[2])
#h = sys.argv[3]
#nh = int(sys.argv[4])

fname = 'initial/file1.vtu'
data = meshio.read(fname)
node = data.points
cell = data.cells[0][1]

mesh = LagrangeTriangleMesh(node*500, cell, p=1)
mesh.uniform_refine(n=0)
mesh = LagrangeWedgeMesh(mesh, h=0.005, nh=1, p=1)

edge = mesh.entity('edge')
node = mesh.entity('node')
cell = mesh.entity('cell')
tface, qface = mesh.entity('face')

print(tface.shape)

mesh.celldata['a'] = np.arange(len(cell))
mesh.to_vtk(fname='write.vtu')