示例#1
0
    def neededVectors(self,
                      short_length,
                      centers=((0,0,0),),
                      ):
        centers = np.array(centers)
        max_centers = np.max(centers, axis=0)
        min_centers = np.min(centers, axis=0)
        extent = max_centers - min_centers

        v1, v2 = self.unitCell()
        l1 = vectorLength(v1)
        l2 = vectorLength(v2)

        size = abs(np.dot(extent + short_length, v1/l1))
        n1 = int(np.ceil(size/l1))

        v1t = np.array([v1[1], -v1[0], 0])
        v1t /= vectorLength(v1t)
        test_vector = np.dot(v2, v1t)*v1t
        lt = vectorLength(test_vector)
        size = abs(np.dot(extent+short_length, test_vector/lt))
        n2 = int(np.ceil(size/lt))

        vectors = np.array([(n1, 0), (0, n2)])

        return vectors
示例#2
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    def relaxationFactor(self):
        if self.relaxation() is None:
            return 1.0
        lr = vectorLength(self.relaxation().get_cell()[2])
        lu = vectorLength(self.__atoms.get_cell()[2])

        return lr/lu
示例#3
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    def defaultParameters(self, parameters=DEFAULT, centers=((0,0,0), )):
        if parameters is DEFAULT:
            parameters = self.surface().defaultParameters()
            parameters = parameters.toDictionary()
            parameters.pop('kpts')
            parameters.pop('vectors')
            parameters = SurfaceLineDefectParameters(**parameters)

        vectors = parameters['vectors']
        if vectors is DEFAULT:
            new_centers = self.rattleAtoms().get_positions()
            tmp_centers = centers
            centers = np.zeros((len(tmp_centers)+len(new_centers), 3), float)
            centers[:len(tmp_centers)] = tmp_centers
            centers[len(tmp_centers):] = new_centers

            s_parameters = self.surface().defaultParameters(
                    parameters=parameters,
                    centers=centers,
                    )
            vectors = np.array(s_parameters['vectors'])
            parameters = parameters.copy(vectors=vectors)

            if len(self.periodicity()) == 1:
                vp = self.periodicity()[0]
                v1, v2 = parameters['vectors']
                if (vectorLength(np.cross(vp, v1))==0):
                    v1 = vp
                elif (vectorLength(np.cross(vp, v2))==0):
                    v2 = vp
                else:
                    raise Exception

                vectors = np.array((v1, v2))
                parameters = parameters.copy(vectors=vectors)


        kpts = parameters['kpts']
        if kpts is DEFAULT:
            s_parameters = self.surface().defaultParameters(
                    parameters=parameters,
                    )
            kpts = s_parameters['kpts']
            parameters = parameters.copy(kpts=kpts)

        cell_size = parameters['cell_size']
        if cell_size is DEFAULT:
            parameters = parameters.copy(cell_size=45)

        return parameters
示例#4
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    def atoms(self, constrained=True, parameters=DEFAULT):
        if parameters is DEFAULT:
            parameters = self.parameters()
        parameters = self.defaultParameters(parameters)
        vectors = np.array(parameters['vectors'])

        lengths = vectorLength(vectors, 1)
        assert lengths.all()

        atoms = self.__atoms.copy()
        pos = atoms.get_positions()
        size = np.array([pos[:, i].max() - pos[:,i].min() for i in range(3)])
        size = size + parameters['length_scales']['correlation_length']

        repeats = (1, 1, vectors[0][0])
        vectors = atoms.cell[2] * vectors[0][0]

        atoms = atoms.repeat(repeats)
        atoms.set_cell(size)
        atoms.cell[2] = vectors
        atoms = removeCopies(atoms)
        atoms = orderAtoms(atoms)

        atoms = self.makeAtomsRelaxed(atoms, self.relaxation())

        return atoms
示例#5
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    def write(self):
        method = self.method()
        images = self.getOriginalImages()
        new_images = []
        for i in range(len(images)-1):
            initial, final = images[i:i+2]
            diff = final.positions - initial.positions
            diff = vectorLength(diff, 1)
            n_images = int(np.ceil(diff.max()/0.3)) - 1
            print 'n_images=%d' % n_images
            t_images = [initial]
            for j in range(n_images):
                temp = t_images[0].copy()
                t_images.append(temp)
            t_images.append(final)
            neb = NEB(t_images)
            neb.interpolate()
            new_images.extend(neb.images[:-1])

        new_images.append(images[-1])
        neb = NEB(new_images)
        kpts = self.baseTask().parameters().kpts()
        self.method().writeNEB(
                runfile=self.runFile(),
                neb=neb,
                kpts=kpts,
                )
示例#6
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    def __init__(self, system, step, end, direction=(0,0,1)):
        self.__step = step
        self.__end = end
        self.__relaxed_value = None
        self.__system = system
        direction = np.array(direction, float)
        self.__diretion = direction/vectorLength(direction)

        API.HasInputs.__init__(self, inputs=system.tasks())
示例#7
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def determineWaveFunctionRange(
        rho,
        r,
        point_density=4,
        density_range=(-3.5, -2.5),
        ):
    min_value = 10**(density_range[0])
    max_value = 10**(density_range[1])
    r = np.array(r)
    dh_cell = gridSpacingCell(r)
    cell = np.array([r[:, -1, 0, 0], r[:, 0, -1, 0], r[:, 0, 0, -1]]) - r[:, 0, 0, 0]
    assert max_value > min_value
    sh = rho.shape
    t_density = np.reshape(rho, (sh[0]*sh[1], sh[2]))
    d_min = t_density.min(axis=0)
    d_max = t_density.max(axis=0)

    z_values = r[2][0,0,:]
    sh = len(z_values)
    z_values = (z_values + cell[2, 2]/2.0) % cell[2, 2] - cell[2, 2]/2.0
    z_values = np.roll(z_values, sh/2)

    d_min = np.roll(d_min, sh/2)
    d_max = np.roll(d_max, sh/2)
    take = z_values > - 5
    take = np.logical_and(take, d_min < max_value)
    take = np.logical_and(take, d_max > min_value)
    z_values = z_values[take]
    d_min = d_min[take]
    d_max = d_max[take]

    padding = dh_cell[2, 2]
    z_span = (z_values.min() - padding, z_values.max() + padding)
    shape = np.zeros(3, int)
    shape[0] = np.ceil(vectorLength(cell[0])*point_density)
    shape[1] = np.ceil(vectorLength(cell[1])*point_density)
    shape[2] = np.ceil((z_span[1] - z_span[0])*point_density + 1)

    X, Y, Z = xy_z(shape=shape, cell=cell, z_span=z_span)
    X -= (X.max() - X.min())/2
    Y -= (Y.max() - Y.min())/2

    return np.array((X, Y, Z))
示例#8
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def getBeyondRangeMask(atoms, position, radius):
    atoms = atoms.copy()
    atoms.translate(-position)
    middle = np.sum(atoms.get_cell(), axis=0)/2.
    atoms.translate(middle)
    atoms = wrap(atoms)
    atoms.translate(-middle)
    beyond_range = vectorLength(atoms.get_positions(), 1) > radius

    return beyond_range
示例#9
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def makeSample(crystal, vectors):
    radius = numpy.max(vectorLength(vectors))
    repeats = findNeededRepetitions(crystal.unitCell(), radius)
    atoms = crystal.toAseAtoms()
    atoms = atoms.repeat(repeats)
    atoms.set_cell(vectors)
    atoms = wrap(atoms)
    atoms = removeCopies(atoms)

    return atoms
示例#10
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def findIndices(find_atoms, atoms, tolerance=1e-5):
    indices = []
    for pos in find_atoms.positions:
        diff = vectorLength(atoms.positions - pos, 1)
        argmin = np.argmin(diff)
        if diff[argmin] > tolerance:
            indices.append(None)
        else:
            indices.append(argmin)

    return indices
示例#11
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def setCellAndPBC(atoms, periodicity):
    dim = len(periodicity)
    if dim == 0:
        pass
    elif dim == 1:
        v0 = np.dot(periodicity, atoms.cell[:2])[0]
        pro = [vectorLength(np.cross(v0, v)) for v in atoms.cell[:2]]
        v1 = atoms.cell[np.argmax(pro)]
        cell = np.array([v0, v1, atoms.cell[2]])
        atoms.set_cell(cell)
    atoms.set_pbc([True]*dim + [False]*(3-dim))
示例#12
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def makeAtomsRelaxed(atoms, relaxed_atoms, tolerance=1.0, cell=None, change=None, correct_drift=False):
    atoms = atoms.copy()
    if relaxed_atoms is None:
        return atoms
    if change is None:
        change = np.ones(len(atoms), np.bool)

    if cell is None:
        cell = atoms.get_cell()
        cell[relaxed_atoms.pbc] = relaxed_atoms.cell[relaxed_atoms.pbc]

    drift = np.zeros(3, np.float)
    used = np.zeros(len(relaxed_atoms), np.bool)
    changed = []
    if relaxed_atoms is not None:
        # Find relaxed atoms closest to originals.
        for i, atom in enumerate(atoms):
            if not change[i]:
                continue
            mask = np.array([r_atom.symbol == atom.symbol for r_atom in relaxed_atoms])
            mask = np.logical_and(mask, np.logical_not(used))

            if mask.sum() == 0:
                continue
            diff = relaxed_atoms.positions[mask] - atom.position
            diff = minimalDistance(diff, cell[relaxed_atoms.pbc])
            index = vectorLength(diff, 1).argmin()
            adjustment = diff[index]
            if vectorLength(adjustment) < tolerance:
                drift += adjustment
                real_index = np.arange(len(relaxed_atoms))[mask][index]
                used[real_index] = False
                changed.append(i)
                atom.position += adjustment

    if correct_drift:
        changed = np.array(changed)
        drift /= len(changed)
        atoms.positions[changed] -= drift

    return atoms
示例#13
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    def notestSaveReadWaveFunctionsTest(self):
        band = 21
        kn = 4
        ws = 2
        potential = Topographic(voltage=-2)
        rho, r, dh_cell = readCubeDensity(label=test_label)
        dh = np.array(map(vectorLength, dh_cell))
        rho = rho.sum(axis=0)
        c, variables, domain = surfaceIntegrator(rho=rho, variables=r, rho0=1e-3, DS=1)
        thick_surface = vectorLength(c, axis=0) > 1e-9
        take_z = thick_surface.sum(axis=0)
        take_z = take_z.sum(axis=0) > 0

        wf, r, dh_cell = readCubeWavefunction(label=test_label, band=band, kn=kn)
        EF, eigs= readEigenvalues(label=test_label)
        kpts = readKpoints(label=test_label)
        energy = eigs[kn-1, band-1, 0]
        we = STMWeighting(energies=[energy], potential=potential, EF=EF)
        we = we[0]

        kpt, wk = kpts[kn-1]
        kappa = getVacuumDecayRate(energy)
        eikr = phaseFactor(kpt, r)
        u = wf/eikr
        grad_u = np.array(np.gradient(u, *dh))
        A = (c*grad_u).sum(axis=0)
        B = u*c
        A=A[:,:,take_z]
        B=B[:,:,:,take_z]
        r=r[:,:,:,take_z]
        u, variables = propagateWaveFunction(
                A=A,
                B=B,
                kpt=kpt,
                r=r,
                kappa=kappa,
                height=10,
                )
        weight = we*ws*wk
        Itest = weight*abs(u)**2

        self.assertFalse(os.path.exists(testfile))
        saveWavefunctionsToPlane(filename=testfile, label=test_label)
        self.assertTrue(os.path.exists(testfile))
        f = netcdf.netcdf_file(testfile, 'r')
        self.assertTrue(len(f.variables.keys()) >0)
        f.close()
        I, r = STMFromFile(
                label=join(test_folder, 'test'),
                potentials=[potential],
                cells=None,
                )
        self.assertArraysEqual(np.log(Itest[0,0]), np.log(I[0,0,0]), 5)
示例#14
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    def modifyAtoms(self, atoms, indices):
        direction = self.direction()
        diff = atoms.positions[indices].mean(axis=0)
        diff = np.dot(diff, direction)
        move = (self.difference() - diff)*direction
        atoms.positions[indices] += move
        w_to = 1
        mode = np.zeros(3*len(atoms))
        for index1 in indices:
            mode[3*index1: 3*(index1+1)] = w_to*direction

        mode /= vectorLength(mode)
        constraint = FixedMode(mode)
        atoms.constraints.append(constraint)

        return atoms
示例#15
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def findPeriodicallyEqualAtoms(atoms, other_atoms):
    center = atoms.positions.mean(axis=0)
    center, remain = convertToBasis(center, other_atoms.cell)
    center = (np.array([.5, .5, .5]) - center)[0]
    other_atoms = wrap(other_atoms, center=center)
    cell = other_atoms.get_cell()
    pbc = atoms.get_pbc()
    cell = atoms.cell[pbc]

    group = -np.ones(len(other_atoms), dtype=np.int)
    for i, atom in enumerate(atoms):
        diff = other_atoms.get_positions() - atom.position
        pos = minimalDistance(diff, cell)
        mask = vectorLength(pos, 1) < 1e-5
        indices = np.arange(len(other_atoms))[mask]
        group[indices] = i

    return group
示例#16
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    def __init__(self,
                 probe_symbol,
                 surface_symbol,
                 ):
        self.__probe_symbol = probe_symbol
        surface = BodyCenteredCubic111(surface_symbol)

        l = vectorLength(surface.cell()[1])/3
        x, y = self.probePlacement(l)
        positions = [(x,y,2.210),
                     (x, y + l, 0.92),
                     (x + l*np.cos(np.pi/6), y-l*np.sin(np.pi/6), 0.92),
                     (x - l*np.cos(np.pi/6),y-l*np.sin(np.pi/6), 0.92),
                     ]
        added_atoms = Atoms(probe_symbol*len(positions), positions)

        SurfacePointDefect.__init__(
                self,
                surface=surface,
                added_atoms=added_atoms,
                )
示例#17
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    def defaultParameters(
            self,
            parameters=DEFAULT,
            centers=((0,0,0),),
            ):
        if parameters is DEFAULT:
            parameters = SurfaceParameters1D()

        scales = parameters['length_scales']
        short_length = scales['short_correlation_length']
        depth = scales.depth()

        in_equal_layers = self.inequivalentLayers()
        electrode_layers = parameters['electrode_layers']
        bound_layers = parameters['bound_layers']
        free_layers = parameters['free_layers']
        if bound_layers is DEFAULT:
            bound_layers = 2
        if electrode_layers is DEFAULT:
            electrode_layers = 0

        size = vectorLength(self.cell('orth_surface')[0])
        if free_layers is DEFAULT:
            n_layers = int(np.ceil(in_equal_layers*depth/size))
            free_layers = n_layers - bound_layers - electrode_layers

        cell_size = parameters['cell_size']

        if cell_size is DEFAULT:
            c_length = parameters['length_scales']['correlation_length']
            cell_size = (c_length, c_length, c_length)

        parameters = parameters.copy(
                free_layers=free_layers,
                bound_layers=bound_layers,
                electrode_layers=electrode_layers,
                cell_size=cell_size,
                )

        return parameters
示例#18
0
def passivateLowerSurface(atoms, direction, length=1, angle=90):
    s_direc = np.sign(direction)
    a_direc = abs(direction) - 1
    max_or_min = {-1: min, 1: max}[s_direc]

    atoms = atoms.copy()
    angle = angle * (math.pi / 180)
    positions = atoms.get_positions()
    z_m = max_or_min(positions[:, a_direc])
    lower_positions = positions[s_direc * positions[:, a_direc] > s_direc * (z_m - s_direc * 0.5)]
    lower_positions[:, 2] = lower_positions[:, 2].min()
    upper_positions = positions[s_direc * positions[:, a_direc] < s_direc * (z_m - s_direc * 0.5)]

    diff = upper_positions - lower_positions[0]
    l = vectorLength(diff, 1)
    not_direction = np.array([i for i in range(3) if i != a_direc], int)
    closest = abs(diff[np.argmin(l)][not_direction])

    if abs(closest[0]) > abs(closest[1]):
        h_positions = [
            position + [0, -length * math.cos(angle), s_direc * length * math.sin(angle)]
            for position in lower_positions
        ]
        h_positions += [
            position + [0, length * math.cos(angle), s_direc * length * math.sin(angle)] for position in lower_positions
        ]
    else:
        h_positions = [
            position + [-length * math.cos(angle), 0, s_direc * length * math.sin(angle)]
            for position in lower_positions
        ]
        h_positions += [
            position + [length * math.cos(angle), 0, s_direc * length * math.sin(angle)] for position in lower_positions
        ]

    new_atoms = Atoms("H%d" % len(h_positions), h_positions, cell=atoms.get_cell(), pbc=atoms.get_pbc())
    new_atoms += atoms

    return new_atoms
示例#19
0
    def make_electrodes(self, atoms):
        unique_electrodes = uniqueElectrodes(atoms.electrodes())
        electodes = []
        for electrode, names in unique_electrodes:
            electrode_atoms = makeElectrodeConform(electrode)
            s_dir = electrode.semiInfiniteDirection()
            parameters = self.parameters.copy()
            label = '_'.join(names)
            label = 'EL_%s' % label
            parameters['label'] = label

            kpts = np.array(parameters['kpts'] )
            l = vectorLength(electrode.cell()[s_dir])
            k = int(np.ceil(400/l))
            kpts[s_dir] = k
            parameters['kpts'] = tuple(kpts)

            electrode_calculator = self.__class__(**parameters)
            electrode_atoms.set_calculator(electrode_calculator)
            electodes.append(electrode_atoms)

        return electodes
示例#20
0
def substitutionalDopingOfMiddleLayer(atoms, n_dopants=1, dopant_element='P', centers=None):
    assert isinstance(n_dopants, int)
    assert n_dopants > 0
    atoms = atoms.copy()
    middle_layer = list(findMiddleLayer(atoms))
    symbols = np.array(atoms.get_chemical_symbols())
    make_dopants = []
    for i in range(n_dopants):
        if centers is None:
            middle_layer_index = 0
            centers = []
        else:
            pos = atoms.positions[np.array(middle_layer, int)]
            for center in centers:
                middle_layer_index = vectorLength(minimalDistance(pos - center, atoms.cell), 1).argmax()

        index = middle_layer.pop(middle_layer_index)
        make_dopants.append(index)
        centers.append(atoms[index].position)

    symbols[np.array(make_dopants, int)] = dopant_element
    atoms.set_chemical_symbols(symbols)

    return atoms
示例#21
0
    def modifyAtoms(self, atoms, indices):

        index2 = indices[-1]
        other_indices = indices[:-1]

        direction = np.array([0, 0, 1.0])
        diff = atoms.positions[index2] - atoms.positions[other_indices].mean(axis=0)
        diff = np.dot(diff, direction)
        move = self.difference()*direction
        move -= diff*direction
        w_other = 1.0/len(indices)
        w2 = 1.0 - w_other
        atoms.positions[index2] += move*w2
        atoms.positions[other_indices] -= move*w_other

        mode = np.zeros(3*len(atoms))
        for index1 in other_indices:
            mode[3*index1: 3*(index1+1)] = w_other*direction
        mode[3*index2: 3*(index2+1)] = -w2*direction
        mode /= vectorLength(mode)
        constraint = FixedMode(mode)
        atoms.constraints.append(constraint)

        return atoms
示例#22
0
    def atoms(self, constrained=True, parameters=DEFAULT):
        parameters = self.defaultParameters(parameters)
        vectors = np.array(parameters['vectors'])

        lengths = vectorLength(vectors, 1)
        assert lengths.all()

        atoms = self.__atoms.copy()

        vectors = convertFromBasis(vectors, atoms.cell)
        repeats = findNeededRepetitions(atoms.cell, 1.5*lengths.max())

        atoms = atoms.repeat(repeats)
        atoms.cell[atoms.pbc] = vectors
        atoms.wrap()
        atoms = removeCopies(atoms)
        atoms.setTag('Reference', picker=None)

        padding = np.logical_not(atoms.pbc)
        assert padding.sum() == 0

        atoms = self.makeAtomsRelaxed(atoms, self.relaxation())

        return atoms
示例#23
0
def saveWavefunctionsToPlane(filename, label='./siesta', density_range=(-3.5, -2.5)):
    rho, r,  dh_cell = readCubeDensity(label=label)
    x, y, z = r
    dh = np.array([dh_cell[0,0], dh_cell[1,1], dh_cell[2,2]])
    eigs, kpts, EF = readInfoForSTMSimulation(label=label)
    eigs, rho, w_s = handleSpinPolarization(eigs, rho)
    is_spin_polarized = w_s == 1
    if is_spin_polarized:
        rho = rho.sum(axis=0)

    energies = np.array(eigs)[:,0]
    i_o = (energies < EF).sum() - 1
    i_u = i_o + 1
    i_t = i_o - 2
    rho0 = 10**(np.array(density_range).mean())
    DS = density_range[1] - density_range[0]
    c, c_r, domain = surfaceIntegrator(rho=rho, variables=r, rho0=rho0, DS=DS)
    thick_surface = vectorLength(c, axis=0) > 1e-9
    take_z = thick_surface.sum(axis=0)
    take_z = take_z.sum(axis=0) > 0
    thick_surface = thick_surface[:,:,take_z]
    x, y, z = c_r

    wfs = []
    EF, energies = readEigenvalues(label=label)
    folder = os.path.dirname(label)
    for wf_filename in os.listdir(folder):
        wf_filename = wf_filename.split('.')
        if wf_filename[0] == 'siesta' and wf_filename[-2] == 'REAL' and wf_filename[-1] == 'cube':
            kn = int(wf_filename[1][1:])
            band = int(wf_filename[2][2:])
            spin = wf_filename[3]
            if is_spin_polarized:
                spin = {'UP':0, 'DOWN':1}[spin]
            elif spin=='DOWN':
                continue
            else:
                spin = 0
            wfs.append((energies[kn-1, band-1, spin], kn-1, band-1, spin))
    wfs.sort()

    nc_defined = False
    f = netcdf.netcdf_file(filename, 'w')
    for i, info in enumerate(wfs):
        energy, kn, band, spin = info
        kpt, w_k = kpts[kn]
        if energy > 0:
            continue
        kappa = getVacuumDecayRate(energy)
        wf, r, dh_cell = readCubeWavefunction(band + 1, kn=kn+1, spin=spin+1, folder=folder)
        eikr = phaseFactor(kpt, r)
        u = wf/eikr

        grad_u = np.array(np.gradient(u, *dh))
        A = (c*grad_u).sum(axis=0)
        r = r[:,:,:, take_z]
        u = u[:,:,take_z]
        A = A[:,:,take_z]
        ct = c[:, :, :, take_z]

        if not nc_defined:
            nwf = f.createDimension('nwf', len(wfs))
            xd = f.createDimension('x', u.shape[0])
            yd = f.createDimension('y', u.shape[1])
            zd = f.createDimension('z', u.shape[2])
            ran = f.createDimension('range', 2)
            points = f.createDimension('points', thick_surface.sum())
            vector3d = f.createDimension('vector3d', 3)
            comp = f.createDimension('complex', 2)
            d_var = f.createVariable('thick_surface', dimensions=('x', 'y', 'z'), type=np.dtype('b'))
            ran_var = f.createVariable('grid_cell', dimensions=('vector3d', 'vector3d'), type=np.dtype('f'))
            ran_var[:] = dh_cell
            origin_var = f.createVariable('origin', dimensions=('vector3d', ), type=np.dtype('f'))
            origin_var[:] = np.array([r[0].min(), r[1].min(), r[2].min()])

            d_var[:] = thick_surface
            c_var = f.createVariable('c', dimensions=('vector3d', 'points'), type=np.dtype('f4'))
            for ci in range(3):
                c_var[ci,:] = ct[ci, thick_surface]
            spin_weight = f.createVariable('spin_weight', dimensions=tuple(), type=np.dtype('i'))
            spin_weight.assignValue(w_s)
            fermi_energy = f.createVariable('EF', dimensions=tuple(), type=np.dtype('f'))
            fermi_energy.assignValue(EF)
            kpts_var = f.createVariable('kpts', type=np.dtype(float), dimensions=('nwf', 'vector3d'))
            wk_var = f.createVariable('wk', type=np.dtype(float), dimensions=('nwf',))
            energy_var = f.createVariable('energy', type=np.dtype(float), dimensions=('nwf',))
            spin_var = f.createVariable('spin', type=np.dtype('i'), dimensions=('nwf',))
            u_var = f.createVariable('u', type=np.dtype('f4'), dimensions=('nwf', 'points', 'complex'))
            A_var = f.createVariable('A', type=np.dtype('f4'), dimensions=('nwf', 'points', 'complex'))

            nc_defined = True

        wk_var[i] = w_k
        kpts_var[i] = kpt
        energy_var[i] = energy
        spin_var[i] = spin
        u_var[i,:, 0] = u[thick_surface].real
        u_var[i,:, 1] = u[thick_surface].imag
        A_var[i,:, 0] = A[thick_surface].real
        A_var[i,:, 1] = A[thick_surface].imag
    f.close()

    return True
示例#24
0
 def __init__(self, difference, direction=(0, 0, 1)):
     self.__difference = difference
     direction = np.array(direction, float)
     self.__direction = direction/vectorLength(direction)