Ejemplo n.º 1
0
    def test_volume_tl(self):
        from sfepy.discrete import FieldVariable

        fu = self.problem.fields['vector']
        fq = self.problem.fields['scalar']

        var_u = FieldVariable('u',
                              'parameter',
                              fu,
                              primary_var_name='(set-to-None)')
        var_q = FieldVariable('q',
                              'test',
                              fq,
                              primary_var_name='(set-to-None)')

        var_u.set_data(nm.linspace(0, 0.004, var_u.n_dof))

        vval = self.problem.evaluate('dw_tl_volume.i.Omega( q, u )',
                                     term_mode='volume',
                                     q=var_q,
                                     u=var_u)

        sval = self.problem.evaluate('d_tl_volume_surface.i.Gamma( u )',
                                     u=var_u)

        ok = abs(vval - sval) < 1e-14

        self.report('TL: by volume: %e == by surface: %e -> %s' %
                    (vval, sval, ok))

        return ok
Ejemplo n.º 2
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    def test_surface_evaluate(self):
        from sfepy.discrete import FieldVariable
        problem = self.problem

        us = problem.get_variables()['us']
        vec = nm.empty(us.n_dof, dtype=us.dtype)
        vec[:] = 1.0
        us.set_data(vec)

        expr = 'ev_surface_integrate.i.Left( us )'
        val = problem.evaluate(expr, us=us)
        ok1 = nm.abs(val - 1.0) < 1e-15
        self.report('with unknown: %s, value: %s, ok: %s'
                    % (expr, val, ok1))

        ps1 = FieldVariable('ps1', 'parameter', us.get_field(),
                            primary_var_name='(set-to-None)')
        ps1.set_data(vec)

        expr = 'ev_surface_integrate.i.Left( ps1 )'
        val = problem.evaluate(expr, ps1=ps1)
        ok2 = nm.abs(val - 1.0) < 1e-15
        self.report('with parameter: %s, value: %s, ok: %s'
                    % (expr, val, ok2))
        ok2 = True

        return ok1 and ok2
Ejemplo n.º 3
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    def test_volume_tl(self):
        from sfepy.discrete import FieldVariable

        fu = self.problem.fields['vector']
        fq = self.problem.fields['scalar']

        var_u = FieldVariable('u', 'parameter', fu,
                              primary_var_name='(set-to-None)')
        var_q = FieldVariable('q', 'test', fq,
                              primary_var_name='(set-to-None)')

        var_u.set_data(nm.linspace(0, 0.004, var_u.n_dof))

        vval = self.problem.evaluate('dw_tl_volume.i.Omega( q, u )',
                                     term_mode='volume', q=var_q, u=var_u)

        sval = self.problem.evaluate('d_tl_volume_surface.i.Gamma( u )',
                                     u=var_u)

        ok = abs(vval - sval) < 1e-14

        self.report('TL: by volume: %e == by surface: %e -> %s' %
                    (vval, sval, ok))

        return ok
Ejemplo n.º 4
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    def test_surface_evaluate(self):
        from sfepy.discrete import FieldVariable
        problem = self.problem

        us = problem.get_variables()['us']
        vec = nm.empty(us.n_dof, dtype=us.dtype)
        vec[:] = 1.0
        us.set_data(vec)

        expr = 'ev_surface_integrate.i.Left( us )'
        val = problem.evaluate(expr, us=us)
        ok1 = nm.abs(val - 1.0) < 1e-15
        self.report('with unknown: %s, value: %s, ok: %s' % (expr, val, ok1))

        ps1 = FieldVariable('ps1',
                            'parameter',
                            us.get_field(),
                            primary_var_name='(set-to-None)')
        ps1.set_data(vec)

        expr = 'ev_surface_integrate.i.Left( ps1 )'
        val = problem.evaluate(expr, ps1=ps1)
        ok2 = nm.abs(val - 1.0) < 1e-15
        self.report('with parameter: %s, value: %s, ok: %s' % (expr, val, ok2))
        ok2 = True

        return ok1 and ok2
Ejemplo n.º 5
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    def create_subequations(self, var_names, known_var_names=None):
        """
        Create sub-equations containing only terms with the given virtual
        variables.

        Parameters
        ----------
        var_names : list
            The list of names of virtual variables.
        known_var_names : list
            The list of  names of (already) known state variables.

        Returns
        -------
        subequations : Equations instance
            The sub-equations.
        """
        from sfepy.discrete import FieldVariable

        known_var_names = get_default(known_var_names, [])

        objs = []
        for iv, var_name in enumerate(var_names):
            terms = [
                term.copy(name=term.name) for eq in self for term in eq.terms
                if term.get_virtual_name() == var_name
            ]

            # Make parameter variables from known state variables in terms
            # arguments.
            for known_name in known_var_names:
                for term in terms:
                    if known_name in term.arg_names:
                        ii = term.arg_names.index(known_name)
                        state = self.variables[known_name]
                        par = FieldVariable(known_name,
                                            'parameter',
                                            state.field,
                                            primary_var_name='(set-to-None)')
                        term.args[ii] = par
                        term._kwargs[known_name] = par
                        par.set_data(state())

            new_terms = Terms(terms)
            objs.append(Equation('eq_%d' % iv, new_terms))

        subequations = Equations(objs)

        return subequations
Ejemplo n.º 6
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    def create_subequations(self, var_names, known_var_names=None):
        """
        Create sub-equations containing only terms with the given virtual
        variables.

        Parameters
        ----------
        var_names : list
            The list of names of virtual variables.
        known_var_names : list
            The list of  names of (already) known state variables.

        Returns
        -------
        subequations : Equations instance
            The sub-equations.
        """
        from sfepy.discrete import FieldVariable

        known_var_names = get_default(known_var_names, [])

        objs = []
        for iv, var_name in enumerate(var_names):
            terms = [term.copy(name=term.name)
                     for eq in self for term in eq.terms
                     if term.get_virtual_name() == var_name]

            # Make parameter variables from known state variables in terms
            # arguments.
            for known_name in known_var_names:
                for term in terms:
                    if known_name in term.arg_names:
                        ii = term.arg_names.index(known_name)
                        state = self.variables[known_name]
                        par = FieldVariable(known_name, 'parameter',
                                            state.field,
                                            primary_var_name='(set-to-None)')
                        term.args[ii] = par
                        term._kwargs[known_name] = par
                        par.set_data(state())

            new_terms = Terms(terms)
            objs.append(Equation('eq_%d' % iv, new_terms))

        subequations = Equations(objs)

        return subequations
Ejemplo n.º 7
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    def test_projection_tri_quad(self):
        from sfepy.discrete.projections import make_l2_projection

        source = FieldVariable('us', 'unknown', self.field)

        coors = self.field.get_coor()
        vals = nm.sin(2.0 * nm.pi * coors[:, 0] * coors[:, 1])
        source.set_data(vals)

        name = op.join(self.options.out_dir,
                       'test_projection_tri_quad_source.vtk')
        source.save_as_mesh(name)

        mesh = Mesh.from_file('meshes/2d/square_quad.mesh',
                              prefix_dir=sfepy.data_dir)
        domain = FEDomain('domain', mesh)

        omega = domain.create_region('Omega', 'all')

        field = Field.from_args('bilinear',
                                nm.float64,
                                'scalar',
                                omega,
                                approx_order=1)

        target = FieldVariable('ut', 'unknown', field)

        make_l2_projection(target, source)

        name = op.join(self.options.out_dir,
                       'test_projection_tri_quad_target.vtk')
        target.save_as_mesh(name)

        bbox = self.field.domain.get_mesh_bounding_box()
        x = nm.linspace(bbox[0, 0] + 0.001, bbox[1, 0] - 0.001, 20)
        y = nm.linspace(bbox[0, 1] + 0.001, bbox[1, 1] - 0.001, 20)

        xx, yy = nm.meshgrid(x, y)
        test_coors = nm.c_[xx.ravel(), yy.ravel()].copy()

        vec1 = source.evaluate_at(test_coors)
        vec2 = target.evaluate_at(test_coors)

        ok = (nm.abs(vec1 - vec2) < 0.01).all()

        return ok
Ejemplo n.º 8
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    def test_projection_tri_quad(self):
        from sfepy.discrete.projections import make_l2_projection

        source = FieldVariable('us', 'unknown', self.field)

        coors = self.field.get_coor()
        vals = nm.sin(2.0 * nm.pi * coors[:,0] * coors[:,1])
        source.set_data(vals)

        name = op.join(self.options.out_dir,
                       'test_projection_tri_quad_source.vtk')
        source.save_as_mesh(name)

        mesh = Mesh.from_file('meshes/2d/square_quad.mesh',
                              prefix_dir=sfepy.data_dir)
        domain = FEDomain('domain', mesh)

        omega = domain.create_region('Omega', 'all')


        field = Field.from_args('bilinear', nm.float64, 'scalar', omega,
                                approx_order=1)

        target = FieldVariable('ut', 'unknown', field)

        make_l2_projection(target, source)

        name = op.join(self.options.out_dir,
                       'test_projection_tri_quad_target.vtk')
        target.save_as_mesh(name)

        bbox = self.field.domain.get_mesh_bounding_box()
        x = nm.linspace(bbox[0, 0] + 0.001, bbox[1, 0] - 0.001, 20)
        y = nm.linspace(bbox[0, 1] + 0.001, bbox[1, 1] - 0.001, 20)

        xx, yy = nm.meshgrid(x, y)
        test_coors = nm.c_[xx.ravel(), yy.ravel()].copy()

        vec1 = source.evaluate_at(test_coors)
        vec2 = target.evaluate_at(test_coors)

        ok = (nm.abs(vec1 - vec2) < 0.01).all()

        return ok
Ejemplo n.º 9
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def save_basis_on_mesh(mesh, options, output_dir, lin,
                       permutations=None, suffix=''):
    if permutations is not None:
        mesh = mesh.copy()
        gel = GeometryElement(mesh.descs[0])
        perms = gel.get_conn_permutations()[permutations]
        conn = mesh.cmesh.get_cell_conn()
        n_el, n_ep = conn.num, gel.n_vertex
        offsets = nm.arange(n_el) * n_ep

        conn.indices[:] = conn.indices.take((perms + offsets[:, None]).ravel())

    domain = FEDomain('domain', mesh)

    omega = domain.create_region('Omega', 'all')
    field = Field.from_args('f', nm.float64, shape=1, region=omega,
                            approx_order=options.max_order,
                            poly_space_base=options.basis)
    var = FieldVariable('u', 'unknown', field)

    if options.plot_dofs:
        import sfepy.postprocess.plot_dofs as pd
        import sfepy.postprocess.plot_cmesh as pc
        ax = pc.plot_wireframe(None, mesh.cmesh)
        ax = pd.plot_global_dofs(ax, field.get_coor(), field.econn)
        ax = pd.plot_local_dofs(ax, field.get_coor(), field.econn)
        if options.dofs is not None:
            ax = pd.plot_nodes(ax, field.get_coor(), field.econn,
                               field.poly_space.nodes,
                               get_dofs(options.dofs, var.n_dof))
        pd.plt.show()

    output('dofs: %d' % var.n_dof)

    vec = nm.empty(var.n_dof, dtype=var.dtype)
    n_digit, _format = get_print_info(var.n_dof, fill='0')
    name_template = os.path.join(output_dir,
                                 'dof_%s%s.vtk' % (_format, suffix))
    for ip in get_dofs(options.dofs, var.n_dof):
        output('dof %d...' % ip)

        vec.fill(0.0)
        vec[ip] = 1.0

        var.set_data(vec)

        if options.derivative == 0:
            out = var.create_output(vec, linearization=lin)

        else:
            out = create_expression_output('ev_grad.ie.Elements(u)',
                                           'u', 'f', {'f' : field}, None,
                                           Variables([var]),
                                           mode='qp', verbose=False,
                                           min_level=lin.min_level,
                                           max_level=lin.max_level,
                                           eps=lin.eps)

        name = name_template % ip
        ensure_path(name)
        out['u'].mesh.write(name, out=out)

        output('...done (%s)' % name)