Ejemplo n.º 1
0
def wrap_cc(cell1, pts):
    """
    Function finds the indices of atoms making tetrahedrons

    Parameters
    -------------
    cell1 :
        The simulation cell ( a 3*4 numpy array where the first 3 columns are the
        cell vectors and the last column is the box origin)
    pts :
        Position of atoms in initial cell, the atoms within an rCut of the initial cell.

    Returns
    ------------
    pts1 :
        Position of atoms in initial cell, the atoms within an rCut of the initial cell,
        and the Voronoi coordinates as the new set of atoms.

    """
    data = ovd.DataCollection()
    data.objects.append(cell1)
    particles = ovd.Particles()
    particles.create_property('Position', data=pts)
    data.objects.append(particles)

    # Create a new Pipeline with a StaticSource as data source:
    pipeline = Pipeline(source=StaticSource(data=data))

    pipeline.modifiers.append(ovm.WrapPeriodicImagesModifier())
    data1 = pipeline.compute()
    pts1 = np.array(data1.particle_properties['Position'][...])
    return pts1
Ejemplo n.º 2
0
def ovito_dxa(atoms, replicate_z=3):
    from ovito.io.ase import ase_to_ovito
    from ovito.modifiers import ReplicateModifier, DislocationAnalysisModifier
    from ovito.pipeline import StaticSource, Pipeline

    data = ase_to_ovito(atoms)
    pipeline = Pipeline(source=StaticSource(data=data))
    pipeline.modifiers.append(ReplicateModifier(num_z=replicate_z))
    dxa = DislocationAnalysisModifier(
        input_crystal_structure=DislocationAnalysisModifier.Lattice.BCC)
    pipeline.modifiers.append(dxa)

    data = pipeline.compute()
    return (np.array(data.dislocations.segments[0].true_burgers_vector),
            data.dislocations.segments[0].length / replicate_z,
            data.dislocations.segments[0])
         #    pass
         #else:
         # atoms = atoms*(2, 2, 2)
         data = ase_to_ovito(atoms)
         node = Pipeline(source=StaticSource(data=data))
 
         node.modifiers.append(modifier)
         #node.modifiers.append(CommonNeighborAnalysisModifier(mode=CommonNeighborAnalysisModifier.Mode.FixedCutoff))
         # node.modifiers.append(CommonNeighborAnalysisModifier(mode=CommonNeighborAnalysisModifier.Mode.AdaptiveCutoff))
         #node.modifiers.append(AcklandJonesModifier())
 
         # node.modifiers.append(BondAngleAnalysisModifier())
         # node.modifiers.append(PolyhedralTemplateMatchingModifier(rmsd_cutoff=0.0))
 
         # Let OVITO's data pipeline do the heavy work.
         node.compute()
 
         # A two-dimensional array containing the three CNA indices
         # computed for each bond in the system.
         atom_classes = list(node.output.particle_properties['Structure Type'].array)
 
 
         #AcklandJonesModifier.Type.OTHER(0)
         #AcklandJonesModifier.Type.FCC(1)
         #AcklandJonesModifier.Type.HCP(2)
         #AcklandJonesModifier.Type.BCC(3)
         #AcklandJonesModifier.Type.ICO(4)
 
         # CommonNeighborAnalysisModifier.Type.OTHER(0)
         # CommonNeighborAnalysisModifier.Type.FCC(1)
         # CommonNeighborAnalysisModifier.Type.HCP(2)