Ejemplo n.º 1
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    def test_ElementDict_to_ElementDict(self):
        # Init 1
        mesh1 = Mesh()
        mesh1.element = ElementDict()
        mesh1.element.connectivity = {
            "Triangle": np.array([[0, 1, 2], [1, 2, 3]])
        }
        mesh1.element.tag = {"Triangle": np.array([1, 2])}
        mesh1.element.nb_elem = {"Triangle": 2}
        mesh1.element.nb_node_per_element = {"Triangle": 3}

        mesh2 = Mesh()
        mesh2.element = ElementMat()
        mesh2.element.connectivity = np.array([[0, 1, 2], [1, 2, 3]])
        mesh2.element.nb_elem = 2
        mesh2.element.nb_node_per_element = 3

        mesh_new = Mesh()
        mesh_new.element = ElementDict()

        # Method test 2
        mesh_new.element.convert_element(mesh1.element)
        # Check results 1
        solution = np.array([[0, 1, 2], [1, 2, 3]
                             ])  # Warning, elements tags, not line position !
        testA = np.sum(
            abs(solution - mesh_new.element.connectivity["Triangle"]))
        msg = ("Wrong projection: returned " +
               str(mesh_new.element.connectivity["Triangle"]) +
               ", expected: " + str(solution))
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)
Ejemplo n.º 2
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    def test_ElementDict(self):
        # Init 1
        mesh = Mesh()
        mesh.element = ElementDict()
        mesh.element.connectivity = {"Triangle": np.array([[0, 1, 2], [1, 2, 3]])}
        mesh.element.tag = {"Triangle": np.array([1, 2])}
        mesh.element.nb_elem = {"Triangle": 2}
        mesh.element.nb_node_per_element = {"Triangle": 3}
        # Method test 1
        elem_tag = mesh.element.get_node2element(1)
        # Check results
        solution = np.array([1, 2])  # Warning, elements tags, not line position !
        testA = np.sum(abs(solution - elem_tag))
        msg = (
            "Wrong projection: returned "
            + str(elem_tag)
            + ", expected: "
            + str(solution)
        )
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)

        # Method test 2
        elem_tag = mesh.element.get_node2element(3)
        solution = np.array([2])
        testA = np.sum(abs(solution - elem_tag))
        msg = (
            "Wrong projection: returned "
            + str(elem_tag)
            + ", expected: "
            + str(solution)
        )
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)
Ejemplo n.º 3
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    def test_ElementDict_NodeMat(self):
        """unittest with ElementDict and NodeMat objects"""
        # Init
        mesh = Mesh()
        mesh.element = ElementDict()
        mesh.node = NodeMat()
        mesh.node.coordinate = np.array([[0, 0], [1, 0], [1, 2], [2, 3]])
        mesh.element.connectivity = {
            "Triangle": np.array([[0, 1, 2], [1, 2, 3]])
        }
        mesh.element.tag = {"Triangle": np.array([1, 2])}
        mesh.element.nb_elem = {"Triangle": 2}
        mesh.element.nb_node_per_element = {"Triangle": 3}
        # Method test 1
        node_tags = mesh.element.get_node_tags(2)
        # Check result
        solution = np.array([1, 2, 3])
        testA = np.sum(abs(solution - node_tags))
        msg = ("Wrong projection: returned " + str(node_tags) +
               ", expected: " + str(solution))
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)

        # Method test 2
        node_tags = mesh.element.get_node_tags(np.array([1, 2]))
        # Check result
        solution = np.array([0, 1, 2, 3])
        testA = np.sum(abs(solution - node_tags))
        msg = ("Wrong projection: returned " + str(node_tags) +
               ", expected: " + str(solution))
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)

        # Method test 3
        node_tags = mesh.element.get_node_tags()
        # Check result
        solution = np.array([0, 1, 2, 3])
        testA = np.sum(abs(solution - node_tags))
        msg = ("Wrong projection: returned " + str(node_tags) +
               ", expected: " + str(solution))
        DELTA = 1e-10
        self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)
Ejemplo n.º 4
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 def test_NodeMat_ElementMat(self):
     """unittest with ElementMat and NodeMat objects"""
     # Init
     mesh = Mesh()
     mesh.element = ElementMat()
     mesh.node = NodeMat()
     mesh.node.coordinate = np.array([[0, 0], [1, 0], [1, 2], [2, 3]])
     mesh.element.connectivity = np.array([[0, 1, 2], [1, 2, 3]])
     mesh.element.nb_elem = 2
     mesh.element.nb_node_per_element = 3
     node_tags = mesh.element.get_node_tags(1)
     # Method test 1
     nodes_coord = mesh.node.get_coord(node_tags)
     # Check result
     solution = np.array([[1, 0], [1, 2], [2, 3]])
     testA = np.sum(abs(solution - nodes_coord))
     msg = ("Wrong projection: returned " + str(node_tags) +
            ", expected: " + str(solution))
     DELTA = 1e-10
     self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)
Ejemplo n.º 5
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def set_submesh(self, group_number):
    """Define a mesh object as submesh of parent mesh object

     Parameters
     ----------
     self : Mesh
         an Mesh object
     group_number : int
         a group number which define the elements which constitute the submesh

     Returns
     -------

     """
    submesh = Mesh()
    submesh.element = self.element.get_group(
        group_number
    )  # Create a new Element object which is restrained to group_number
    submesh.node = self.node.get_group(
        element=submesh.element
    )  # Create a new Node object which corresponds to selection of element
Ejemplo n.º 6
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 def test_ElementMat(self):
     # Init 1
     mesh = Mesh()
     mesh.element = ElementMat()
     mesh.element.connectivity = np.array(
         [[11, 12, 13], [0, 1, 2], [1, 2, 3], [120, 11, 12]]
     )
     mesh.element.nb_elem = 2
     mesh.element.nb_node_per_element = 3
     # Method test 1
     elem_tag = mesh.element.get_node2element(1)
     # Check results
     solution = np.array([1, 2])  # In this case, element tag = line position
     testA = np.sum(abs(solution - elem_tag))
     msg = (
         "Wrong projection: returned "
         + str(elem_tag)
         + ", expected: "
         + str(solution)
     )
     DELTA = 1e-10
     self.assertAlmostEqual(testA, 0, msg=msg, delta=DELTA)
Ejemplo n.º 7
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def get_meshsolution(self, is_get_mesh, is_save_FEA, save_path, j_t0):
    """Load the mesh data and solution data. FEMM must be working and a simulation must have been solved.

    Parameters
    ----------
    self : MagFEMM
        a MagFEMM object
    is_get_mesh : bool
        1 to load the mesh and solution into the simulation
    is_save_FEA : bool
        1 to save the mesh and solution into a .json file
    j_t0 : int
        Targeted time step

    Returns
    -------
    res_path: str
        path to the result folder
    """
    # TODO: Not saving the mesh (only the solution) when the sliding band is activated

    idworker = "1"  # For parallelization TODO

    path_txt = join(MAIN_DIR, "Functions", "FEMM") + "\\"
    path_txt_lua = path_txt.replace("\\", "/")
    path_lua_in = join(path_txt, "get_mesh_data_FEMM.lua")
    path_lua_out = join(save_path, "get_mesh_data_FEMM" + idworker + ".lua")
    path_txt_out = save_path + "\\"
    path_txt_out = path_txt_out.replace("\\", "/")

    # Create a new LUA script with current paths
    file_lua = open(path_lua_in, "r")
    text_lua = file_lua.read()
    file_lua.close()
    text_lua = text_lua.replace("my_path_txt", path_txt_out)
    text_lua = text_lua.replace("my_id_worker", idworker)

    file_lua_out = open(path_lua_out, "w")
    file_lua_out.write(text_lua)
    file_lua_out.close()

    # Run the LUA externally using FEMM LUA console and store the data in the
    # temporary text files
    path_lua_out2 = path_lua_out.replace("\\", "/")
    callfemm('dofile("' + path_lua_out2 + '")')

    # Delete the LUA script
    os.remove(path_lua_out)

    # Read the nodes and elements files
    path_node = join(save_path, "nodes" + idworker + ".txt")
    path_element = join(save_path, "elements" + idworker + ".txt")
    listNd0 = np.loadtxt(path_node, delimiter=" ")
    listElem0 = np.loadtxt(path_element, dtype="i", delimiter=" ")
    NbNd = len(listNd0)
    NbElem = len(listElem0)

    # Node list
    listNd = np.zeros(shape=(NbNd, 3))
    listNd[:, 0] = listNd0[:, 0]
    listNd[:, 1] = listNd0[:, 1]

    # Element list
    # listElem = np.zeros(shape=(NbElem, 3))
    listElem = listElem0[:, 0:3] - 1

    # Delete text files
    os.remove(path_node)
    os.remove(path_element)

    # Read the results file
    path_results = join(save_path, "results" + idworker + ".txt")
    results = np.loadtxt(path_results, delimiter=" ")

    # Delete text files
    os.remove(path_results)

    # Save data
    if is_get_mesh:

        # Create Mesh and Solution dictionaries
        mesh = Mesh()
        mesh.element = ElementMat(
            connectivity=listElem,
            nb_elem=NbElem,
            group=listElem0[:, 6],
            nb_node_per_element=3,
        )
        mesh.node = NodeMat(coordinate=listNd[:, 0:2], nb_node=NbNd)

        solution = SolutionFEMM(B=results[:, 0:2], H=results[:, 2:4], mu=results[:, 4])

        meshFEMM = MeshSolution(name="FEMM_magnetic_mesh", mesh=mesh, solution=solution)

        if is_save_FEA:
            save_path_fea = join(save_path, "meshFEMM" + str(j_t0) + ".json")
            meshFEMM.save(save_path_fea)

        return meshFEMM