Exemple #1
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    def init_md(self, name, time_step=0.5, temp_init=300, temp_bath=None, reset=False, interval=1):
        """
        Initialize an ase molecular dynamics trajectory. The logfile needs to be specifies, so that old trajectories
        are not overwritten. This functionality can be used to subsequently carry out equilibration and production.

        Args:
            name (str): Basic name of logfile and trajectory
            time_step (float): Time step in fs (default=0.5)
            temp_init (float): Initial temperature of the system in K (default is 300)
            temp_bath (float): Carry out Langevin NVT dynamics at the specified temperature. If set to None, NVE
                               dynamics are performed instead (default=None)
            reset (bool): Whether dynamics should be restarted with new initial conditions (default=False)
            interval (int): Data is stored every interval steps (default=1)
        """

        # If a previous dynamics run has been performed, don't reinitialize velocities unless explicitely requested
        # via restart=True
        if not self.dynamics or reset:
            self._init_velocities(temp_init=temp_init)

        # Set up dynamics
        if temp_bath is None:
            self.dynamics = VelocityVerlet(self.molecule, time_step * units.fs)
        else:
            self.dynamics = Langevin(self.molecule, time_step * units.fs, temp_bath * units.kB, 0.01)

        # Create monitors for logfile and a trajectory file
        logfile = os.path.join(self.working_dir, "%s.log" % name)
        trajfile = os.path.join(self.working_dir, "%s.traj" % name)
        logger = MDLogger(self.dynamics, self.molecule, logfile, stress=False, peratom=False, header=True, mode='a')
        trajectory = Trajectory(trajfile, 'w', self.molecule)

        # Attach monitors to trajectory
        self.dynamics.attach(logger, interval=interval)
        self.dynamics.attach(trajectory.write, interval=interval)
Exemple #2
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    def __call__(self, atoms):
        self.set_atoms(atoms)
        self.backup()

        # Start med en temperatur!
        dyn = Langevin(atoms, self.timestep, self.temp, self.friction)
        dyn.run(self.steps)
Exemple #3
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    def create_system(self,
                      name,
                      time_step=1.0,
                      temp=300,
                      temp_init=None,
                      restart=False,
                      store=1,
                      nvt=False,
                      friction=0.001):
        """
        Parameters
        -----------
        name : str
            Name for output files.
        time_step : float, optional
            Time step in fs for simulation.
        temp : float, optional
            Temperature in K for NVT simulation.
        temp_init : float, optional
            Optional different temperature for initialization than thermostate set at.
        restart : bool, optional
            Determines whether simulation is restarted or not, 
            determines whether new velocities are initialized.
        store : int, optional
            Frequency at which output is written to log files.
        nvt : bool, optional
            Determines whether to run NVT simulation, default is False.
        friction : float, optional
            friction coefficient in fs^-1 for Langevin integrator
        """
        if temp_init is None: temp_init = temp
        if not self.md or restart:
            MaxwellBoltzmannDistribution(self.mol, temp_init * units.kB)

        if not nvt:
            self.md = VelocityVerlet(self.mol, time_step * units.fs)
        else:
            self.md = Langevin(self.mol, time_step * units.fs, temp * units.kB,
                               friction / units.fs)

        logfile = os.path.join(self.tmp, "{}.log".format(name))
        trajfile = os.path.join(self.tmp, "{}.traj".format(name))

        logger = MDLogger(self.md,
                          self.mol,
                          logfile,
                          stress=False,
                          peratom=False,
                          header=True,
                          mode="a")
        trajectory = Trajectory(trajfile, "w", self.mol)
        self.md.attach(logger, interval=store)
        self.md.attach(trajectory.write, interval=store)
Exemple #4
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def test_CO2linear_Au111_langevin(testdir):
    """Test Langevin with constraints for rigid linear
    triatomic molecules"""

    rng = np.random.RandomState(0)
    eref = 3.133526

    zpos = cos(134.3 / 2.0 * pi / 180.0) * 1.197
    xpos = sin(134.3 / 2.0 * pi / 180.0) * 1.19
    co2 = Atoms('COO',
                positions=[(-xpos + 1.2, 0, -zpos), (-xpos + 1.2, -1.1, -zpos),
                           (-xpos + 1.2, 1.1, -zpos)])

    slab = fcc111('Au', size=(2, 2, 4), vacuum=2 * 5, orthogonal=True)
    slab.center()
    add_adsorbate(slab, co2, 1.5, 'bridge')
    slab.set_pbc((True, True, False))
    d0 = co2.get_distance(-3, -2)
    d1 = co2.get_distance(-3, -1)
    d2 = co2.get_distance(-2, -1)

    calc = EMT()
    slab.calc = calc
    constraint = FixLinearTriatomic(triples=[(-2, -3, -1)])
    slab.set_constraint(constraint)

    fr = 0.1
    dyn = Langevin(slab,
                   2.0 * units.fs,
                   temperature_K=300,
                   friction=fr,
                   trajectory='langevin_%.1f.traj' % fr,
                   logfile='langevin_%.1f.log' % fr,
                   loginterval=20,
                   rng=rng)
    dyn.run(100)

    # Check that the temperature is within a reasonable range
    T = slab.get_temperature()
    assert T > 100
    assert T < 500

    # Check that the constraints work
    assert abs(slab.get_distance(-3, -2, mic=1) - d0) < 1e-9
    assert abs(slab.get_distance(-3, -1, mic=1) - d1) < 1e-9
    assert abs(slab.get_distance(-2, -1, mic=1) - d2) < 1e-9

    # If the energy differs from the reference energy
    # it is most probable that the redistribution of
    # random forces in Langevin is not working properly
    assert abs(slab.get_potential_energy() - eref) < 1e-4
Exemple #5
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    def run(self, calc, filename):
        slab = self.starting_geometry.copy()
        slab.set_calculator(calc)
        np.random.seed(1)
        MaxwellBoltzmannDistribution(slab, self.temp * units.kB)
        if self.ensemble == "NVE":
            dyn = VelocityVerlet(slab, self.dt * units.fs)
        elif self.ensemble == "nvtberendsen":
            dyn = nvtberendsen.NVTBerendsen(slab,
                                            self.dt * units.fs,
                                            self.temp,
                                            taut=300 * units.fs)
        elif self.ensemble == "langevin":
            dyn = Langevin(slab, self.dt * units.fs, self.temp * units.kB,
                           0.002)
        traj = ase.io.Trajectory(filename + ".traj", "w", slab)
        dyn.attach(traj.write, interval=1)
        try:
            fixed_atoms = len(slab.constraints[0].get_indices())
        except:
            fixed_atoms = 0
            pass

        def printenergy(a=slab):
            """Function to print( the potential, kinetic, and total energy)"""
            epot = a.get_potential_energy() / len(a)
            ekin = a.get_kinetic_energy() / (len(a) - fixed_atoms)
            print("Energy per atom: Epot = %.3feV Ekin = %.3feV (T=%3.0fK) "
                  "Etot = %.3feV" % (epot, ekin, ekin /
                                     (1.5 * units.kB), epot + ekin))

        if printenergy:
            dyn.attach(printenergy, interval=10)
        dyn.run(self.count)
def generate_data(count, filename, temp, hook, cons_t=False):
    """Generates test or training data with a simple MD simulation."""
    traj = ase.io.Trajectory(filename, "w")
    slab = fcc100("Cu", size=(3, 3, 3))
    ads = molecule("CO")
    add_adsorbate(slab, ads, 5, offset=(1, 1))
    cons = FixAtoms(indices=[
        atom.index for atom in slab if (atom.tag == 2 or atom.tag == 3)
    ])
    if hook:
        cons2 = Hookean(a1=28, a2=27, rt=1.58, k=10.0)
        slab.set_constraint([cons, cons2])
    else:
        slab.set_constraint(cons)
    slab.center(vacuum=13., axis=2)
    slab.set_pbc(True)
    slab.wrap(pbc=[True] * 3)
    slab.set_calculator(EMT())
    slab.get_forces()
    dyn = QuasiNewton(slab)
    dyn.run(fmax=0.05)
    traj.write(slab)
    if cons_t is True:
        dyn = Langevin(slab, 1.0 * units.fs, temp * units.kB, 0.002)
    else:
        dyn = VelocityVerlet(slab, dt=1.0 * units.fs)
    for step in range(count):
        dyn.run(20)
        traj.write(slab)
def md_run(images, count, calc, filename, dir, temp, cons_t=False):
    """Generates test or training data with a simple MD simulation."""
    log = Logger("results/logs/" + filename + ".txt")
    traj = ase.io.Trajectory("".join([dir, filename, ".traj"]), "w")
    slab = images[0].copy()
    slab.set_calculator(calc)
    slab.get_forces()
    traj.write(slab)
    if cons_t is True:
        dyn = Langevin(slab, 1.0 * units.fs, temp * units.kB, 0.002)
    else:
        dyn = VelocityVerlet(slab, dt=1.0 * units.fs)
    time_start = time.time()
    for step in range(count):
        dyn.run(20)
        traj.write(slab)
    time_elapsed = time.time() - time_start
    log("MD Simulation Dynamics: %s" % dyn)
    log("MD Simulation Time: %s \n" % time_elapsed)
Exemple #8
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def test_fixrotation_asap(asap3):
    rng = np.random.RandomState(123)

    with seterr(all='raise'):
        atoms = bulk('Au', cubic=True).repeat((3, 3, 10))
        atoms.pbc = False
        atoms.center(vacuum=5.0 + np.max(atoms.cell) / 2)
        print(atoms)
        atoms.calc = asap3.EMT()
        MaxwellBoltzmannDistribution(atoms, temperature_K=300, force_temp=True,
                                     rng=rng)
        Stationary(atoms)
        check_inertia(atoms)
        md = Langevin(
            atoms,
            timestep=20 * fs,
            temperature_K=300,
            friction=1e-3,
            logfile='-',
            loginterval=500,
            rng=rng)
        fx = FixRotation(atoms)
        md.attach(fx)
        md.run(steps=1000)
        check_inertia(atoms)
def generate_data(count, filename, temp, hook, cons_t=False):
    """Generates test or training data with a simple MD simulation."""
    traj = ase.io.Trajectory(filename, "w")
    pair = molecule("CO")
    cons = Hookean(a1=0, a2=1, rt=1.58, k=10.0)
    # pair.set_constraint(cons)
    pair.set_calculator(EMT())
    pair.get_potential_energy()
    dyn = QuasiNewton(pair, trajectory=(filename[:-5] + "_relax.traj"))
    dyn.run(fmax=0.05)
    traj.write(pair)
    MaxwellBoltzmannDistribution(pair, temp * units.kB)
    if cons_t is True:
        dyn = Langevin(pair, 5 * units.fs, temp * units.kB, 0.002)
    else:
        dyn = VelocityVerlet(pair, dt=1.0 * units.fs)
    for step in range(count - 1):
        dyn.run(50)
        traj.write(pair)
Exemple #10
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def test_langevin_asap(asap3):
    with seterr(all='raise'):
        rng = np.random.RandomState(0)
        a = bulk('Au', cubic=True).repeat((4, 4, 4))
        a.pbc = (False, False, False)
        a.center(vacuum=2.0)
        print(a)
        a.calc = asap3.EMT()
        # Set temperature to 10 K
        MaxwellBoltzmannDistribution(a,
                                     temperature_K=10,
                                     force_temp=True,
                                     rng=rng)
        Stationary(a)
        assert abs(a.get_temperature() - 10) < 0.0001
        # Langevin dynamics should raise this to 300 K
        T = 300
        md = Langevin(a,
                      timestep=4 * fs,
                      temperature_K=T,
                      friction=0.01,
                      logfile='-',
                      loginterval=500,
                      rng=rng)
        md.run(steps=3000)
        # Now gather the temperature over 10000 timesteps, collecting it
        # every 5 steps
        temp = []
        for i in range(1500):
            md.run(steps=5)
            temp.append(a.get_temperature())
        temp = np.array(temp)
        avgtemp = np.mean(temp)
        fluct = np.std(temp)
        print("Temperature is {:.2f} K +/- {:.2f} K".format(avgtemp, fluct))
        assert abs(avgtemp - T) < 10.0
Exemple #11
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atoms.center()
atoms = atoms.repeat((3, 3, 3))
atoms.set_pbc(True)

# Set constraints for rigid triatomic molecules
nm = 27
atoms.constraints = FixLinearTriatomic(triples=[(3 * i, 3 * i + 1, 3 * i + 2)
                                                for i in range(nm)])

tag = 'acn_27mol_300K'
atoms.calc = ACN(rc=np.min(np.diag(atoms.cell)) / 2)

# Create Langevin object
md = Langevin(atoms,
              1 * units.fs,
              temperature=300 * units.kB,
              friction=0.01,
              logfile=tag + '.log')

traj = Trajectory(tag + '.traj', 'w', atoms)
md.attach(traj.write, interval=1)
md.run(5000)

# Repeat box and equilibrate further
atoms.set_constraint()
atoms = atoms.repeat((2, 2, 2))
nm = 216
atoms.constraints = FixLinearTriatomic(triples=[(3 * i, 3 * i + 1, 3 * i + 2)
                                                for i in range(nm)])

tag = 'acn_216mol_300K'
Exemple #12
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    a.set_calculator(calc)
    FIRE(a).run(fmax=fmax, steps=10000)

    # Langevin quench to T1
    print 'Langevin quench to {0}...'.format(T1)
    Langevin(a, dt*fs, T1*kB, 1.0/(500*fs),
             logfile='-', loginterval=int(100/dt)).run(int(time/dt))

    # Langevin quench to T2
    print 'Langevin quench to {0}...'.format(T2)
    Langevin(a, dt*fs, T2*kB, 1.0/(500*fs),
             logfile='-', loginterval=int(100/dt)).run(int(time/dt))

    # Langevin quench to T3
    print 'Langevin quench to {0}...'.format(T3)
    dyn = Langevin(a, dt*fs, T3*kB, 1.0/(500*fs), logfile='-',
                   loginterval=int(100/dt))
    dyn.run(int(time/dt))

    # Collect pair distribution function
    print 'Collect pair distribution function...'
    p = PairAndAngleDistribution(a.get_calculator(), g2_cutoff, coord_cutoff,
                                 npairbins=nbins, nanglebins=nbins)
    dyn.attach(p, interval=int(100/dt))
    dyn.run(int(time/dt))

    print 'Writing files...'

    # Write snapshot
    write('rho_{0}.traj'.format(density), a)

    # Write pair distribution function
Exemple #13
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add_adsorbate(slab, co2, 1.5, 'bridge')
slab.set_pbc((True, True, False))
d0 = co2.get_distance(-3, -2)
d1 = co2.get_distance(-3, -1)
d2 = co2.get_distance(-2, -1)

calc = EMT()
slab.set_calculator(calc)
constraint = FixLinearTriatomic(triples=[(-2, -3, -1)])
slab.set_constraint(constraint)

fr = 0.1
dyn = Langevin(slab,
               2.0 * units.fs,
               300 * units.kB,
               fr,
               trajectory='langevin_%.1f.traj' % fr,
               logfile='langevin_%.1f.log' % fr,
               loginterval=20,
               rng=rng)
dyn.run(100)

# Check that the temperature is within a reasonable range
T = slab.get_temperature()
assert T > 100
assert T < 500

# Check that the constraints work
assert abs(slab.get_distance(-3, -2, mic=1) - d0) < 1e-9
assert abs(slab.get_distance(-3, -1, mic=1) - d1) < 1e-9
assert abs(slab.get_distance(-2, -1, mic=1) - d2) < 1e-9
Exemple #14
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# Global
# Stationary(atoms)

## Dynamics
# from ase.md.verlet import VelocityVerlet
# dyn = VelocityVerlet(
    # atoms,
    # d_t,
    # trajectory = label+'.traj',
    # logfile = 'log_'+label+'.txt',
    # )
from ase.md import Langevin
dyn = Langevin(
    atoms       = atoms,
    timestep    = 10 *units.fs,
    temperature = temp,
    friction    = friction,
    trajectory  = label+'.traj',
    logfile     = 'log-'+label+'.txt',
    ) 
# from ase.md.npt import NPT
# dyn = NPT(
    # atoms = atoms,
    # timestep = d_t,
    # temperature = temp,
    # externalstress = 0.,
    # ttime = 75 * units.fs,
    # pfactor = (75. *units.fs)**2 * 100. *units.GPa,
    # trajectory  = label+'.traj',
    # logfile     = 'log_'+label+'.txt',
    # )
### relax option
Exemple #15
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def run():
    rng = np.random.RandomState(0)
    a = Atoms('4X',
              masses=[1, 2, 3, 4],
              positions=[(0, 0, 0), (1, 0, 0), (0, 1, 0), (0.1, 0.2, 0.7)],
              calculator=TstPotential())
    print(a.get_forces())
    # Langevin should reproduce Verlet if friction is 0.
    md = Langevin(a,
                  0.5 * fs,
                  temperature_K=300,
                  friction=0.0,
                  logfile='-',
                  loginterval=500)
    traj = Trajectory('4N.traj', 'w', a)
    md.attach(traj, 100)
    e0 = a.get_total_energy()
    md.run(steps=2000)
    del traj
    assert abs(read('4N.traj').get_total_energy() - e0) < 0.0001

    # Try again with nonzero friction.
    md = Langevin(a,
                  0.5 * fs,
                  temperature_K=300,
                  friction=0.001,
                  logfile='-',
                  loginterval=500,
                  rng=rng)
    traj = Trajectory('4NA.traj', 'w', a)
    md.attach(traj, 100)
    md.run(steps=2000)

    # We cannot test the temperature without a lot of statistics.
    # Asap does that.  But if temperature is quite unreasonable,
    # something is very wrong.
    T = a.get_temperature()
    assert T > 50
    assert T < 1000

    qn = QuasiNewton(a)
    qn.run(0.001)
    assert abs(a.get_potential_energy() - 1.0) < 0.000002
Exemple #16
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    # Relax with the unscreened potential
    print 'Relax with quick potential...'
    a.set_calculator(quick_calc)
    FIRE(a).run(fmax=fmax, steps=10000)

    # Relax with the screened potential
    print 'Relax with proper potential...'
    a.set_calculator(calc)
    FIRE(a).run(fmax=fmax, steps=10000)

    # Langevin quench to T1
    print 'Langevin quench to {0}...'.format(T1)
    Langevin(a,
             dt * fs,
             T1 * kB,
             1.0 / (500 * fs),
             logfile='-',
             loginterval=int(100 / dt)).run(int(time / dt))

    # Langevin quench to T2
    print 'Langevin quench to {0}...'.format(T2)
    Langevin(a,
             dt * fs,
             T2 * kB,
             1.0 / (500 * fs),
             logfile='-',
             loginterval=int(100 / dt)).run(int(time / dt))

    # Langevin quench to T3
    print 'Langevin quench to {0}...'.format(T3)
    dyn = Langevin(a,
Exemple #17
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class ASE_MD:
    """
    Setups and runs the MD simulation. Serves as an interface to the EVB Hamiltonian class and ASE.
    """
    def __init__(self,
                 ase_atoms,
                 tmp,
                 calc_omm_d1,
                 calc_omm_d2,
                 calc_nn_d1,
                 calc_nn_d2,
                 off_diag,
                 shift=0):
        """
        Parameters
        -----------
        ase_atoms : str
            Location of input structure, gets created to ASE Atoms object.
        tmp : str
            Location for tmp directory.
        calc_omm_d1 : Object
            Contains OpenMM force field for diabat 1.
        calc_omm_d2 : Object
            Contains OpenMM force field for diabat 2.
        calc_nn_d1 : Object
            Diabat_NN instance for diabat 1.
        calc_nn_d2 : Object
            Diabat NN instance for diabat 2.
        off_diag : PyTorch model
            Model for predicting H12 energy and forces.
        shift : float
            Diabat 2 energy shift to diabat 1 reference.
        """

        self.tmp = tmp
        if not os.path.isdir(self.tmp):
            os.makedirs(self.tmp)

        self.mol = read(ase_atoms)
        calculator = EVB_Hamiltonian(calc_omm_d1, calc_omm_d2, calc_nn_d1,
                                     calc_nn_d2, off_diag, shift)
        self.mol.set_calculator(calculator)
        self.md = None

    def create_system(self,
                      name,
                      time_step=1.0,
                      temp=300,
                      temp_init=None,
                      restart=False,
                      store=1,
                      nvt=False,
                      friction=0.001):
        """
        Parameters
        -----------
        name : str
            Name for output files.
        time_step : float, optional
            Time step in fs for simulation.
        temp : float, optional
            Temperature in K for NVT simulation.
        temp_init : float, optional
            Optional different temperature for initialization than thermostate set at.
        restart : bool, optional
            Determines whether simulation is restarted or not, 
            determines whether new velocities are initialized.
        store : int, optional
            Frequency at which output is written to log files.
        nvt : bool, optional
            Determines whether to run NVT simulation, default is False.
        friction : float, optional
            friction coefficient in fs^-1 for Langevin integrator
        """
        if temp_init is None: temp_init = temp
        if not self.md or restart:
            MaxwellBoltzmannDistribution(self.mol, temp_init * units.kB)

        if not nvt:
            self.md = VelocityVerlet(self.mol, time_step * units.fs)
        else:
            self.md = Langevin(self.mol, time_step * units.fs, temp * units.kB,
                               friction / units.fs)

        logfile = os.path.join(self.tmp, "{}.log".format(name))
        trajfile = os.path.join(self.tmp, "{}.traj".format(name))

        logger = MDLogger(self.md,
                          self.mol,
                          logfile,
                          stress=False,
                          peratom=False,
                          header=True,
                          mode="a")
        trajectory = Trajectory(trajfile, "w", self.mol)
        self.md.attach(logger, interval=store)
        self.md.attach(trajectory.write, interval=store)

    def write_mol(self, name, ftype="xyz", append=False):
        """
        Write out current molecule structure.
        Parameters
        -----------
        name : str
            Name of the output file.
        ftype : str, optional
            Determines output file format, default xyz.
        append : bool, optional
            Append to existing output file or not.
        """
        path = os.path.join(self.tmp, "{}.{}".format(name, ftype))
        write(path, self.mol, format=ftype, append=append)

    def run_md(self, steps):
        """
        Run MD simulation.
        Parameters
        -----------
        steps : int
            Number of MD steps
        """
        self.md.run(steps)
Exemple #18
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            n = a.get_atomic_numbers().copy()

            # Relax with the quick potential
            a.set_atomic_numbers([6]*len(a))
            a.set_calculator(quick_calc)
            FIRE(a, downhill_check=True).run(fmax=1.0, steps=nsteps_relax)
            a.set_atomic_numbers(n)
            write(initial_fn, a)
        else:
            print('... reading %s ...' % liquid_fn)
            a = read(liquid_fn)

        # Thermalize with the slow (but correct) potential
        a.set_calculator(calc)
        traj = Trajectory(liquid_fn, 'a', a)
        dyn = Langevin(a, dt1, T1, 1.0/tau1,
                       logfile='-', loginterval=int(dtdump/dt1))
        dyn.attach(traj.write, interval=int(dtdump/dt1)) # every 100 fs
        nsteps = int(teq/dt1)-len(traj)*int(dtdump/dt1)
        print('Need to run for further {} steps to reach total of {} steps.'.format(nsteps, int(teq/dt1)))
        if nsteps <= 0:
            nsteps = 1
        dyn.run(nsteps)
        traj.close()

        # Write snapshot
        write(liquid_final_fn, a)
    else:
        print('... reading %s ...' % liquid_final_fn)
        a = read(liquid_final_fn)
        a.set_calculator(calc)

def save(smiles, species, coordinates):
    print(len(species))
    print(smiles)
    for s, c in zip(species, coordinates):
        print(s, *c)


smiles = parser.smiles
m = Chem.MolFromSmiles(smiles)
m = Chem.AddHs(m)
AllChem.EmbedMolecule(m, useRandomCoords=True)
AllChem.UFFOptimizeMolecule(m)
pos = m.GetConformer().GetPositions()
natoms = m.GetNumAtoms()
species = [m.GetAtomWithIdx(j).GetSymbol() for j in range(natoms)]

atoms = Atoms(species, positions=pos)

atoms.calc = EMT()
md = Langevin(atoms,
              1 * units.fs,
              temperature=parser.temperature * units.kB,
              friction=0.01)

for _ in range(parser.conformations):
    md.run(1)
    positions = atoms.get_positions()
    save(smiles, species, positions)
Exemple #20
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            n = a.get_atomic_numbers().copy()

            # Relax with the quick potential
            a.set_atomic_numbers([6]*len(a))
            a.set_calculator(quick_calc)
            FIRE(a, downhill_check=True).run(fmax=1.0, steps=10000)
            a.set_atomic_numbers(n)
            write(initial_fn, a)
        else:
            print('... reading %s ...' % liquid_fn)
            a = read(liquid_fn)

        # Thermalize with the slow (but correct) potential
        a.set_calculator(calc)
        traj = Trajectory(liquid_fn, 'a', a)
        dyn = Langevin(a, dt1, T1, 1.0/tau1,
                       logfile='-', loginterval=int(dtdump/dt1))
        dyn.attach(traj.write, interval=int(dtdump/dt1)) # every 100 fs
        nsteps = int(teq/dt1)-len(traj)*int(dtdump/dt1)
        print('Need to run for further {} steps to reach total of {} steps.'.format(nsteps, int(teq/dt1)))
        if nsteps <= 0:
            nsteps = 1
        dyn.run(nsteps)
        traj.close()

        # Write snapshot
        write(liquid_final_fn, a)
    else:
        print('... reading %s ...' % liquid_final_fn)
        a = read(liquid_final_fn)
        a.set_calculator(calc)
Exemple #21
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from ase.md import Langevin
from ase.io import Trajectory, read
from ase.optimize import QuasiNewton
from ase.utils import seterr

with seterr(all='raise'):
    a = Atoms('4X',
              masses=[1, 2, 3, 4],
              positions=[(0, 0, 0),
                         (1, 0, 0),
                         (0, 1, 0),
                         (0.1, 0.2, 0.7)],
              calculator=TestPotential())
    print(a.get_forces())
    # Langevin should reproduce Verlet if friction is 0.
    md = Langevin(a, 0.5 * fs, 300 * kB, 0.0, logfile='-', loginterval=500)
    traj = Trajectory('4N.traj', 'w', a)
    md.attach(traj, 100)
    e0 = a.get_total_energy()
    md.run(steps=10000)
    del traj
    assert abs(read('4N.traj').get_total_energy() - e0) < 0.0001

    # Try again with nonzero friction.
    md = Langevin(a, 0.5 * fs, 300 * kB, 0.001, logfile='-', loginterval=500)
    traj = Trajectory('4NA.traj', 'w', a)
    md.attach(traj, 100)
    md.run(steps=10000)

    # We cannot test the temperature without a lot of statistics.
    # Asap does that.  But if temperature is quite unreasonable,
Exemple #22
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class AseInterface:
    """
    Interface for ASE calculations (optimization and molecular dynamics)

    Args:
        molecule_path (str): Path to initial geometry
        ml_model (object): Trained model
        working_dir (str): Path to directory where files should be stored
        device (str): cpu or cuda
    """
    def __init__(
            self,
            molecule_path,
            ml_model,
            working_dir,
            device="cpu",
            energy="energy",
            forces="forces",
            energy_units="eV",
            forces_units="eV/Angstrom",
            environment_provider=SimpleEnvironmentProvider(),
    ):
        # Setup directory
        self.working_dir = working_dir
        if not os.path.exists(self.working_dir):
            os.makedirs(self.working_dir)

        # Load the molecule
        self.molecule = None
        self._load_molecule(molecule_path)

        # Set up calculator
        calculator = SpkCalculator(
            ml_model,
            device=device,
            energy=energy,
            forces=forces,
            energy_units=energy_units,
            forces_units=forces_units,
            environment_provider=environment_provider,
        )
        self.molecule.set_calculator(calculator)

        # Unless initialized, set dynamics to False
        self.dynamics = False

    def _load_molecule(self, molecule_path):
        """
        Load molecule from file (can handle all ase formats).

        Args:
            molecule_path (str): Path to molecular geometry
        """
        file_format = os.path.splitext(molecule_path)[-1]
        if file_format == "xyz":
            self.molecule = read_xyz(molecule_path)
        else:
            self.molecule = read(molecule_path)

    def save_molecule(self, name, file_format="xyz", append=False):
        """
        Save the current molecular geometry.

        Args:
            name (str): Name of save-file.
            file_format (str): Format to store geometry (default xyz).
            append (bool): If set to true, geometry is added to end of file
                (default False).
        """
        molecule_path = os.path.join(self.working_dir,
                                     "%s.%s" % (name, file_format))
        if file_format == "xyz":
            # For extended xyz format, plain is needed since ase can not parse
            # the extxyz it writes
            write_xyz(molecule_path, self.molecule, plain=True)
        else:
            write(molecule_path,
                  self.molecule,
                  format=file_format,
                  append=append)

    def calculate_single_point(self):
        """
        Perform a single point computation of the energies and forces and
        store them to the working directory. The format used is the extended
        xyz format. This functionality is mainly intended to be used for
        interfaces.
        """
        energy = self.molecule.get_potential_energy()
        forces = self.molecule.get_forces()
        self.molecule.energy = energy
        self.molecule.forces = forces

        self.save_molecule("single_point", file_format="extxyz")

    def init_md(
        self,
        name,
        time_step=0.5,
        temp_init=300,
        temp_bath=None,
        reset=False,
        interval=1,
    ):
        """
        Initialize an ase molecular dynamics trajectory. The logfile needs to
        be specifies, so that old trajectories are not overwritten. This
        functionality can be used to subsequently carry out equilibration and
        production.

        Args:
            name (str): Basic name of logfile and trajectory
            time_step (float): Time step in fs (default=0.5)
            temp_init (float): Initial temperature of the system in K
                (default is 300)
            temp_bath (float): Carry out Langevin NVT dynamics at the specified
                temperature. If set to None, NVE dynamics are performed
                instead (default=None)
            reset (bool): Whether dynamics should be restarted with new initial
                conditions (default=False)
            interval (int): Data is stored every interval steps (default=1)
        """

        # If a previous dynamics run has been performed, don't reinitialize
        # velocities unless explicitly requested via restart=True
        if not self.dynamics or reset:
            self._init_velocities(temp_init=temp_init)

        # Set up dynamics
        if temp_bath is None:
            self.dynamics = VelocityVerlet(self.molecule, time_step * units.fs)
        else:
            self.dynamics = Langevin(
                self.molecule,
                time_step * units.fs,
                temp_bath * units.kB,
                1.0 / (100.0 * units.fs),
            )

        # Create monitors for logfile and a trajectory file
        logfile = os.path.join(self.working_dir, "%s.log" % name)
        trajfile = os.path.join(self.working_dir, "%s.traj" % name)
        logger = MDLogger(
            self.dynamics,
            self.molecule,
            logfile,
            stress=False,
            peratom=False,
            header=True,
            mode="a",
        )
        trajectory = Trajectory(trajfile, "w", self.molecule)

        # Attach monitors to trajectory
        self.dynamics.attach(logger, interval=interval)
        self.dynamics.attach(trajectory.write, interval=interval)

    def _init_velocities(self,
                         temp_init=300,
                         remove_translation=True,
                         remove_rotation=True):
        """
        Initialize velocities for molecular dynamics

        Args:
            temp_init (float): Initial temperature in Kelvin (default 300)
            remove_translation (bool): Remove translation components of
                velocity (default True)
            remove_rotation (bool): Remove rotation components of velocity
                (default True)
        """
        MaxwellBoltzmannDistribution(self.molecule, temp_init * units.kB)
        if remove_translation:
            Stationary(self.molecule)
        if remove_rotation:
            ZeroRotation(self.molecule)

    def run_md(self, steps):
        """
        Perform a molecular dynamics simulation using the settings specified
        upon initializing the class.

        Args:
            steps (int): Number of simulation steps performed
        """
        if not self.dynamics:
            raise AttributeError("Dynamics need to be initialized using the"
                                 " 'setup_md' function")

        self.dynamics.run(steps)

    def optimize(self, fmax=1.0e-2, steps=1000):
        """
        Optimize a molecular geometry using the Quasi Newton optimizer in ase
        (BFGS + line search)

        Args:
            fmax (float): Maximum residual force change (default 1.e-2)
            steps (int): Maximum number of steps (default 1000)
        """
        name = "optimization"
        optimize_file = os.path.join(self.working_dir, name)
        optimizer = QuasiNewton(
            self.molecule,
            trajectory="%s.traj" % optimize_file,
            restart="%s.pkl" % optimize_file,
        )
        optimizer.run(fmax, steps)

        # Save final geometry in xyz format
        self.save_molecule(name)

    def compute_normal_modes(self, write_jmol=True):
        """
        Use ase calculator to compute numerical frequencies for the molecule

        Args:
            write_jmol (bool): Write frequencies to input file for
                visualization in jmol (default=True)
        """
        freq_file = os.path.join(self.working_dir, "normal_modes")

        # Compute frequencies
        frequencies = Vibrations(self.molecule, name=freq_file)
        frequencies.run()

        # Print a summary
        frequencies.summary()

        # Write jmol file if requested
        if write_jmol:
            frequencies.write_jmol()
Exemple #23
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from ase.calculators.test import TestPotential
from ase.md import Langevin
from ase.io import Trajectory, read
from ase.optimize import QuasiNewton
from ase.utils import seterr

rng = np.random.RandomState(0)

with seterr(all='raise'):
    a = Atoms('4X',
              masses=[1, 2, 3, 4],
              positions=[(0, 0, 0), (1, 0, 0), (0, 1, 0), (0.1, 0.2, 0.7)],
              calculator=TestPotential())
    print(a.get_forces())
    # Langevin should reproduce Verlet if friction is 0.
    md = Langevin(a, 0.5 * fs, 300 * kB, 0.0, logfile='-', loginterval=500)
    traj = Trajectory('4N.traj', 'w', a)
    md.attach(traj, 100)
    e0 = a.get_total_energy()
    md.run(steps=10000)
    del traj
    assert abs(read('4N.traj').get_total_energy() - e0) < 0.0001

    # Try again with nonzero friction.
    md = Langevin(a,
                  0.5 * fs,
                  300 * kB,
                  0.001,
                  logfile='-',
                  loginterval=500,
                  rng=rng)