Exemplo n.º 1
0
    def test_map2Dto3D_y(self):
        M2 = discretize.TensorMesh([3, 4])
        M3 = discretize.TensorMesh([3, 2, 4])
        m = np.random.rand(M2.nC)

        for m2to3 in [
            maps.Surject2Dto3D(M3, normal="Y"),
        ]:
            # m2to3 = maps.Surject2Dto3D(M3, normal='Y')
            m = np.arange(m2to3.nP)
            self.assertTrue(m2to3.test())
            self.assertTrue(m2to3.testVec())
            self.assertTrue(
                np.all(utils.mkvc((m2to3 * m).reshape(M3.vnC, order="F")[:, 0, :]) == m)
            )
Exemplo n.º 2
0
###############################################################################
# Mappings
# ---------
#
# Mappings are used to take the inversion model and represent it as electrical
# conductivity on the inversion mesh. We will invert for log-conductivity below
# the surface, fixing the conductivity of the air cells to 1e-8 S/m

# create a 2D mesh that includes air cells
mesh2D = discretize.TensorMesh([mesh.hx, mesh.hz], x0=mesh.x0[[0, 2]])
active_inds = mesh2D.gridCC[:, 1] < 0  # active indices are below the surface


mapping = (
    maps.Surject2Dto3D(mesh)
    * maps.InjectActiveCells(  # populates 3D space from a 2D model
        mesh2D, active_inds, sigma_air
    )
    * maps.ExpMap(  # adds air cells
        nP=inversion_mesh.nC
    )  # takes the exponential (log(sigma) --> sigma)
)

###############################################################################
# True Model
# ----------
#
# Create our true model which we will use to generate synthetic data for

m_true = np.log(sigma_deep) * np.ones(inversion_mesh.nC)