Пример #1
0
 def __init__(self, atoms, indices=None, name='ir', delta=0.01,
              nfree=2, directions=None):
     assert nfree in [2, 4]
     self.atoms = atoms
     if indices is None:
         indices = range(len(atoms))
     self.indices = np.asarray(indices)
     self.nfree = nfree
     self.name = name + '-d%.3f' % delta
     self.delta = delta
     self.H = None
     if directions is None:
         self.directions = np.asarray([0, 1, 2])
     else:
         self.directions = np.asarray(directions)
     self.ir = True
     self.ram = False
     if str(type(self.atoms[0])) == "<class 'ase.atoms.Atoms'>":
         self.imagetype='atoms'
         fixed_atoms = constraints.constrained_indices(atoms[0])
         allatoms = np.array(range(0,len(atoms[0])))
         self.free_atoms = [i for i in allatoms if i not in fixed_atoms]
         self.free_list = range(0,len(self.free_atoms))
         self.atom = atoms[0].copy()
     else:
         self.imagetype='pickle'
         if atoms.constraints:
             print('WARNING! \n Your Atoms object is constrained. '
                   'Some forces may be unintended set to zero. \n')
         self.calc = atoms.get_calculator()
Пример #2
0
def test_getindices():
    from ase.build import fcc111
    from ase.constraints import (FixAtoms, FixBondLengths, FixLinearTriatomic,
                                 FixInternals, Hookean, constrained_indices)

    slab = fcc111('Pt', (4, 4, 4))

    C1 = FixAtoms([0, 2, 4])
    C2 = FixBondLengths([[0, 1], [0, 2]])
    C3 = FixInternals(bonds=[[1, [7, 8]], [1, [8, 9]]])
    C4 = Hookean(a1=30, a2=40, rt=1.79, k=5.)
    C5 = FixLinearTriatomic(triples=[(0, 1, 2), (3, 4, 5)])

    slab.set_constraint([C1, C2, C3, C4, C5])
    assert all(
        constrained_indices(slab, (FixAtoms, FixBondLengths)) == [0, 1, 2, 4])
    assert all(
        constrained_indices(slab, (FixBondLengths,
                                   FixLinearTriatomic)) == [0, 1, 2, 3, 4, 5])
    assert all(
        constrained_indices(slab) == [0, 1, 2, 3, 4, 5, 7, 8, 9, 30, 40])
Пример #3
0
def main():
    arg = sys.argv
    paras = readinputs(arg[1])
    print paras
    start_atom = int(paras['start_atom'])
    end_atom = int(paras['end_atom'])
    shift_targets = numpy.array(
        [int(field) for field in paras['shift_targets'].split()])
    dstrain = float(paras['dstrain'])
    fixed_direction = paras['fix_direction']
    #read geometry
    p1 = read(filename=paras['start_structure'], index=0, format='vasp')
    bond_length = p1.get_distance(start_atom, end_atom)
    fixed_atoms = constrained_indices(p1)
    working_dir = os.getcwd()
    #move atoms based on the given strain and submit jobs
    drs = interpolate(p1[start_atom], p1[end_atom], dstrain,
                      int(paras['njobs']))
    #print new_atoms
    i = 0
    log = open('stretch.dat', 'w')
    for dr in drs:
        for target in shift_targets:
            p1[target].position += dr
        job_i = working_dir + '/' + str(i)
        make_dir(job_i)
        write(filename=job_i + '/POSCAR', images=p1, format='vasp')
        fix_atoms(filename=job_i + '/POSCAR',
                  fixed_atoms=[end_atom],
                  fixed_direction=fixed_direction)
        log.write("%4d %8.6f\n" % (i, i * dstrain * bond_length))
        i += 1
        os.system('cp POTCAR ' + job_i)
        os.system('cp KPOINTS ' + job_i)
        os.system('cp INCAR ' + job_i)
        os.system('cp ' + paras['job_submit_script'] + ' ' + job_i)
        with cd(job_i):
            os.system(paras['job_submit_cmd'] + ' ' +
                      paras['job_submit_script'])
            print os.getcwd(), 'is submitted'
        print 'Back to directory', os.getcwd()
 def __init__(self, atoms, indices=None, name='vib', delta=0.01, nfree=2):
     assert nfree in [2, 4]
     self.atoms = atoms
     if indices is None:
         indices = range(len(atoms))
     self.indices = np.asarray(indices)
     self.name = name
     self.delta = delta
     self.nfree = nfree
     self.H = None
     self.ir = None
     self.ram = None
     if str(type(self.atoms[0])) == "<class 'ase.atoms.Atoms'>":
         self.imagetype = 'atoms'
         fixed_atoms = constraints.constrained_indices(atoms[0])
         allatoms = np.array(range(0, len(atoms[0])))
         self.free_atoms = [i for i in allatoms if i not in fixed_atoms]
         self.free_list = range(0, len(self.free_atoms))
         self.atom = atoms[0].copy()
     else:
         self.imagetype = 'pickle'
Пример #5
0
def main():
    arg = sys.argv
    paras = readinputs(arg[1])
    print paras
    target_atom = int(paras['target_atom'])
    #set strain
    fixed_direction = [int(field) for field in paras['fix_direction'].split()]
    #read geometry
    p1 = read(filename=paras['start_structure'], index=0, format='vasp')
    p2 = read(filename=paras['end_structure'], index=0, format='vasp')
    fixed_atoms = constrained_indices(p1)
    working_dir = os.getcwd()
    #move atoms based on the given strain and submit jobs
    print p1[target_atom]
    new_atoms = interpolate(p1[target_atom], p2[target_atom],
                            int(paras['image_numb']))
    #print new_atoms
    i = 0
    for atom in new_atoms:
        p1[target_atom].position = atom
        job_i = working_dir + '/' + str(i)
        make_dir(job_i)
        write(filename=job_i + '/POSCAR', images=p1, format='vasp')
        fix_atoms(filename=job_i + '/POSCAR',
                  fixed_atoms=[target_atom],
                  fixed_directions=fixed_direction)
        i += 1
        os.system('cp POTCAR ' + job_i)
        os.system('cp KPOINTS ' + job_i)
        os.system('cp INCAR ' + job_i)
        os.system('cp ' + paras['job_submit_script'] + ' ' + job_i)
        with cd(job_i):
            os.system(paras['job_submit_cmd'] + ' ' +
                      paras['job_submit_script'])
            print os.getcwd(), 'is submitted'
        print 'Back to directory', os.getcwd()
Пример #6
0
from ase.build import fcc111
from ase.constraints import (FixAtoms, FixBondLengths, FixInternals, Hookean,
                             constrained_indices)

slab = fcc111('Pt', (4, 4, 4))

C1 = FixAtoms([0, 2, 4])
C2 = FixBondLengths([[0, 1], [0, 2]])
C3 = FixInternals(bonds=[[1, [7, 8]], [1, [8, 9]]])
C4 = Hookean(a1=30, a2=40, rt=1.79, k=5.)

slab.set_constraint([C1, C2, C3, C4])
assert all(
    constrained_indices(slab, (FixAtoms, FixBondLengths)) == [0, 1, 2, 4])
assert all(constrained_indices(slab) == [0, 1, 2, 4, 7, 8, 9, 30, 40])
Пример #7
0
def pca_xyz(traj_dict, fig_title=None):
    """Perform a PCA analysis for the trajectories.
    Parameters
    ----------
    traj_dict: dict
        Dictionary of calculation types and trajectories.
        e.g.: {'oal': oal_traj}, where oal_traj is an ASE Trajectory
        object or the path to the trajectory.
        or {'oal': [path_to_oal_traj, path_to_oal_db]}, where path_to_oal_traj
        is the path to the trajectory and path_to_oal_db is the path to the ase Database.
        or {'oal': [list_of_atoms]}, where the list of atoms serves as a trajectory to be read

    fig_title: str
        Title of the PCA plot.
    """
    types = []
    trajs = []
    pos = []
    energy = []
    for key, value in traj_dict.items():
        types.append(key)
        if isinstance(value, str):
            value = Trajectory(value)
            trajs.append(value)
        elif type(value) is list and type(value[0]) is Atoms:
            trajs.append(value)
        elif isinstance(value, list):
            traj = Trajectory(value[0])
            db = connect(value[1])
            dft_call = [i.id - 1 for i in db.select(check=True)]
            dft_traj = [traj[i] for i in dft_call]
            trajs.append(dft_traj)
        else:
            trajs.append(value)
    # assuming constraints (FixAtom) are applied to the same atoms
    constrained_id = constrained_indices(trajs[0][0])
    for i in trajs:
        all_pos = [j.get_positions() for j in i]
        free_atom_pos = [np.delete(i, constrained_id, 0) for i in all_pos]
        pos.append([j.get_positions() for j in i])
        energy.append([j.get_potential_energy() for j in i])
    label = []
    for i in range(len(types)):
        label += [types[i]] * len(pos[i])
    attr = []
    for i in range(1, np.shape(pos[0])[1] + 1):
        attr.append("%dx" % i)
        attr.append("%dy" % i)
        attr.append("%dz" % i)
    df = []
    for i in range(len(pos)):
        reshape = np.array(pos[i]).reshape(np.shape(pos[i])[0], np.shape(pos[i])[1] * 3)
        df.append(pd.DataFrame(reshape, columns=attr))
    df = pd.concat([df[i] for i in range(len(df))], ignore_index=True)

    df.insert(len(df.columns), "label", label)

    x = df.loc[:, attr].values
    x = StandardScaler().fit_transform(x)

    pca = PCA(n_components=2)
    principalComponents = pca.fit_transform(x)
    principalDf = pd.DataFrame(
        data=principalComponents,
        columns=["principal component 1", "principal component 2"],
    )
    finalDf = pd.concat([principalDf, df[["label"]]], axis=1)

    fig = plt.figure(figsize=(8, 8))
    ax = fig.add_subplot(1, 1, 1)
    ax.set_xlabel("Principal Component 1", fontsize=15)
    ax.set_ylabel("Principal Component 2", fontsize=15)
    if fig_title is not None:
        ax.set_title(fig_title, fontsize=20)
    else:
        ax.set_title("Principal Component Analysis", fontsize=20)
    targets = types
    colors = energy
    mark = ["x", "s", "o", "^", "v", "<", ">", "D"]
    for target, color, mark in zip(targets, colors, mark):
        indicesToKeep = finalDf["label"] == target
        #     if target == 'oal':
        ax.scatter(
            finalDf.loc[indicesToKeep, "principal component 1"],
            finalDf.loc[indicesToKeep, "principal component 2"],
            c=color,
            marker=mark,
            cmap="viridis",
            s=50,
            label=target,
        )
        ax.plot(
            finalDf.loc[indicesToKeep, "principal component 1"],
            finalDf.loc[indicesToKeep, "principal component 2"],
        )
    sm = plt.cm.ScalarMappable(cmap="viridis")
    colorbar = fig.colorbar(sm)
    colorbar.set_label("-log(abs(energy))")
    ax.legend()
    plt.savefig("pca.png")
Пример #8
0
                          bothways=True,
                          skin=skin_arg)
        nl.update(atoms)

        adsorbate_atoms = [
            index for index, atom in enumerate(atoms)
            if atom.symbol not in surface_atoms
        ]

        normals, mask = generate_normals(atoms,
                                         adsorbate_atoms=adsorbate_atoms,
                                         normalize_final=True)
        ### make sure to manually set the normals for 2-D materials, all atoms should have a normal pointing up, as all atoms are surface atoms
        #normals, mask = np.ones((len(atoms), 3)) * (0, 0, 1), list(range(len(atoms)))

        constrained = constrained_indices(atoms)
        mask = [index for index in mask if index not in constrained]
        #for index in mask:
        #    atoms[index].tag = 1

        atoms.set_velocities(normals / 10)

        all_sites = []

        full_graph, envs = process_atoms(atoms,
                                         nl=nl,
                                         adsorbate_atoms=adsorbate_atoms,
                                         radius=3)
        ### here the default radii as well as grid are considered, these can also be added as args.

        for coord in [1, 2, 3]:
Пример #9
0
from ase.build import fcc111
from ase.constraints import (FixAtoms, FixBondLengths, FixInternals, Hookean,
                             constrained_indices)

slab = fcc111('Pt', (4, 4, 4))

C1 = FixAtoms([0, 2, 4])
C2 = FixBondLengths([[0, 1], [0, 2]])
C3 = FixInternals(bonds=[[1, [7, 8]], [1, [8, 9]]])
C4 = Hookean(a1=30, a2=40, rt=1.79, k=5.)

slab.set_constraint([C1, C2, C3, C4])
assert all(constrained_indices(slab, (FixAtoms, FixBondLengths)) ==
           [0, 1, 2, 4])
assert all(constrained_indices(slab) == [0, 1, 2, 4, 7, 8, 9, 30, 40])
Пример #10
0
def main():
    arg = sys.argv
    paras = readinputs(arg[1])
    print paras
    boundary_atoms = numpy.array(
        [float(field) for field in paras['boundary_atoms'].split()])
    #numpy.array([0, 1, 2, 38, 39])
    boundary = numpy.array(
        [float(field) for field in paras['boundary'].split()])
    #([0, 4.407, 0])
    strain = numpy.array([float(field) for field in paras['strain'].split()])
    strain_direction = paras['strain_direction']
    span = float(paras['span'])
    active_space = ([field for field in paras['active_space'].split()])
    #initialize strain for each direction
    dx = numpy.zeros(len(strain))
    dy = dx
    dz = dx
    #set strain
    if strain_direction == 'x':
        dx = strain
        fixed_direction = 1
    if strain_direction == 'y':
        dy = strain
        fixed_direction = 2
    if strain_direction == 'z':
        dz = strain
        fixed_direction = 3
    #read geometry
    p1 = read(filename=paras['structure_file'], index=0, format='vasp')
    fixed_atoms = constrained_indices(p1)
    working_dir = os.getcwd()
    #move atoms based on the given strain and submit jobs
    stretched = open('streched.dat', 'w')
    for i in range(0, len(strain)):
        p2 = p1.copy()
        for atom in p2:
            if atom.index in fixed_atoms or atom.symbol not in active_space:
                continue
            #move atoms at the boundary. Keep the original shape of the boundary
            if atom.index in boundary_atoms:
                atom.position = atom.position + (span * dx[i], span * dy[i],
                                                 span * dz[i])
                continue
            #move other atoms.
            #atom.position = tuple(boundary + (numpy.array(atom.position) - boundary)*numpy.array([1+dx[i],1+dy[i],1+dz[i]]))
        if strain[i] < 0:
            job_i = working_dir + '/' + 'c_' + str(i)
        else:
            job_i = working_dir + '/' + str(i)
        stretched.write("%4d %12.8f \n" % (i, span * strain[i]))
        make_dir(job_i)
        write(filename=job_i + '/POSCAR', images=p2, format='vasp')
        fix_atoms(filename=job_i + '/POSCAR',
                  fixed_atoms=boundary_atoms,
                  fixed_direction=fixed_direction)
        os.system('cp POTCAR ' + job_i)
        os.system('cp KPOINTS ' + job_i)
        os.system('cp INCAR ' + job_i)
        os.system('cp ' + paras['job_submit_script'] + ' ' + job_i)
        with cd(job_i):
            os.system(paras['job_submit_cmd'] + ' ' +
                      paras['job_submit_script'])
            print os.getcwd(), 'is submitted'
        print 'Back to directory', os.getcwd()
Пример #11
0
from ase.build import fcc111
from ase.constraints import (FixAtoms, FixBondLengths, FixLinearTriatomic,
                             FixInternals, Hookean, constrained_indices)

slab = fcc111('Pt', (4, 4, 4))

C1 = FixAtoms([0, 2, 4])
C2 = FixBondLengths([[0, 1], [0, 2]])
C3 = FixInternals(bonds=[[1, [7, 8]], [1, [8, 9]]])
C4 = Hookean(a1=30, a2=40, rt=1.79, k=5.)
C5 = FixLinearTriatomic(triples=[(0, 1, 2), (3, 4, 5)])

slab.set_constraint([C1, C2, C3, C4, C5])
assert all(
    constrained_indices(slab, (FixAtoms, FixBondLengths)) == [0, 1, 2, 4])
assert all(
    constrained_indices(slab, (FixBondLengths,
                               FixLinearTriatomic)) == [0, 1, 2, 3, 4, 5])
assert all(constrained_indices(slab) == [0, 1, 2, 3, 4, 5, 7, 8, 9, 30, 40])