Ejemplo n.º 1
0
def my_error_function(rr):
    # Get a unique path for GULP jobs from the MPI rank. Set to '0' for serial jobs
    try:
        path = str(pool.rank)
    except:
        path = '0'

    # Calculate Ground State
    md_gs_job = gulp.job(path=path)
    md_gs_job.structure = gt_gs
    md_gs_job.forcefield = ezff.generate_forcefield(template,
                                                    rr,
                                                    FFtype='reaxff')
    md_gs_job.options['pbc'] = False
    md_gs_job.options['relax_atoms'] = False
    md_gs_job.options['relax_cell'] = False
    # Run GULP calculation
    md_gs_job.run(command='gulp')
    # Read output from completed GULP job and clean-up
    md_gs_energy = md_gs_job.read_energy()
    md_gs_job.cleanup()

    # Calculate PES Scan for frequency error
    md_freq_scan_job = gulp.job(path=path)
    md_freq_scan_job.structure = gt_freq_scan
    md_freq_scan_job.forcefield = ezff.generate_forcefield(template,
                                                           rr,
                                                           FFtype='reaxff')
    md_freq_scan_job.options['pbc'] = False
    md_freq_scan_job.options['relax_atoms'] = False
    md_freq_scan_job.options['relax_cell'] = False
    # Run GULP calculation
    md_freq_scan_job.run(command='gulp')
    # Read output from completed GULP job and clean-up
    md_freq_scan_energy = md_freq_scan_job.read_energy()
    md_freq_scan_job.cleanup()

    # Calculate PES Scan for dissociation error
    md_full_scan_job = gulp.job(path=path)
    md_full_scan_job.structure = gt_full_scan
    md_full_scan_job.forcefield = ezff.generate_forcefield(template,
                                                           rr,
                                                           FFtype='reaxff')
    md_full_scan_job.options['pbc'] = False
    md_full_scan_job.options['relax_atoms'] = False
    md_full_scan_job.options['relax_cell'] = False
    # Run GULP calculation
    md_full_scan_job.run(command='gulp')
    # Read output from completed GULP job and clean-up
    md_full_scan_energy = md_full_scan_job.read_energy()
    md_full_scan_job.cleanup()

    # Calculate error
    freq_error = ezff.error_energy(md_freq_scan_energy - md_gs_energy,
                                   gt_freq_scan_energy - gt_gs_energy,
                                   weights='minima')
    dissociation_error = ezff.error_energy(md_full_scan_energy - md_gs_energy,
                                           gt_full_scan_energy - gt_gs_energy,
                                           weights='dissociation')
    return [freq_error, dissociation_error]
Ejemplo n.º 2
0
def my_error_function(rr):
    # Get a unique path for GULP jobs from the MPI rank. Set to '0' for serial jobs
    try:
        path = str(pool.rank)
    except:
        path = '0'

    # Calculate Ground State
    md_gs_job = rxmd.job(path=path)
    md_gs_job.structure = gt_gs
    md_gs_job.forcefield = ezff.generate_forcefield(template,
                                                    rr,
                                                    FFtype='reaxff2',
                                                    outfile=md_gs_job.path +
                                                    '/ffield')
    # Run rxmd calculation
    md_gs_job.run(command='rxmd')
    # Read output from completed GULP job and clean-up
    md_gs_energy = md_gs_job.read_energy()
    md_gs_job.cleanup()

    # Calculate PES Scan for frequency error
    md_freq_scan_job = rxmd.job(path=path)
    md_freq_scan_job.structure = gt_freq_scan
    md_freq_scan_job.forcefield = ezff.generate_forcefield(
        template,
        rr,
        FFtype='reaxff2',
        outfile=md_freq_scan_job.path + '/ffield')
    # Run RXMD calculation
    md_freq_scan_job.run(command='rxmd')
    # Read output from completed RXMD job and clean-up
    md_freq_scan_energy = md_freq_scan_job.read_energy()
    md_freq_scan_job.cleanup()

    # Calculate PES Scan for dissociation error
    md_full_scan_job = rxmd.job(path=path)
    md_full_scan_job.structure = gt_full_scan
    md_full_scan_job.forcefield = ezff.generate_forcefield(
        template,
        rr,
        FFtype='reaxff2',
        outfile=md_full_scan_job.path + '/ffield')
    # Run RXMD calculation
    md_full_scan_job.run(command='rxmd')
    # Read output from completed RXMD job and clean-up
    md_full_scan_energy = md_full_scan_job.read_energy()
    #md_full_scan_job.cleanup()

    # Calculate error
    freq_error = ezff.error_energy(md_freq_scan_energy - md_gs_energy,
                                   gt_freq_scan_energy - gt_gs_energy,
                                   weights='minima')
    dissociation_error = ezff.error_energy(md_full_scan_energy - md_gs_energy,
                                           gt_full_scan_energy - gt_gs_energy,
                                           weights='dissociation')
    return [freq_error, dissociation_error]
Ejemplo n.º 3
0
def my_error_function(rr):
    # Get a unique path for GULP jobs from the MPI rank. Set to '0' for serial jobs
    try:
        path = str(pool.rank)
    except:
        path = '0'

    # Calculate Ground State Charges
    md_gs_job = gulp.job(path = path)
    md_gs_job.structure = gt_gs
    md_gs_job.forcefield = ezff.generate_forcefield(template, rr, FFtype = 'reaxff')
    md_gs_job.options['pbc'] = False
    md_gs_job.options['relax_atoms'] = False
    md_gs_job.options['relax_cell'] = False
    md_gs_job.options['atomic_charges'] = True
    # Run GULP calculation
    md_gs_job.run(command='gulp')
    # Read output from completed GULP job and clean-up
    md_gs_atomic_charges = md_gs_job.read_atomic_charges()
    md_gs_job.cleanup()

    # Calculate Relaxation
    md_relax_job = gulp.job(path = path)
    md_relax_job.structure = gt_gs
    md_relax_job.forcefield = ezff.generate_forcefield(template, rr, FFtype = 'reaxff')
    md_relax_job.options['pbc'] = False
    md_relax_job.options['relax_atoms'] = True
    md_relax_job.options['relax_cell'] = False
    md_relax_job.options['atomic_charges'] = True
    # Run GULP calculation
    md_relax_job.run(command='gulp')
    # Read output from completed GULP job and clean-up
    md_relax = md_relax_job.read_structure()
    md_relax_job.cleanup()

    # Calculate error
    charg_error = ezff.error_atomic_charges(MD=md_gs_atomic_charges, GT=gt_gs_atomic_charges)
    disp_error = ezff.error_structure_distortion(MD=md_relax, GT=gt_gs)
    return [charg_error, disp_error]
Ejemplo n.º 4
0
def my_error_function(variable_values):
    # Get rank from pool
    try:
        myrank = pool.rank
    except:
        myrank = 0

    # Configure GULP job.
    path = str(myrank)
    md_job = gulp.job(path=path)
    md_job.structure = gt_structure
    md_job.forcefield = ezff.generate_forcefield(template,
                                                 variable_values,
                                                 FFtype='SW')
    md_job.options['pbc'] = True
    md_job.options['relax_atoms'] = True
    md_job.options['relax_cell'] = True

    # Submit job and read output
    md_job.run()

    # Calculate errors in lattice constant and elastic modulus
    moduli = md_job.read_elastic_moduli(
    )  # 6X6 elastic modulus tensor inside a list of length 1 (for a single input structure)
    md_bulk_modulus = np.mean([
        moduli[0][i, i] for i in range(3)
    ])  # Bulk modulus is sum of diagonal elements in moduli[0]
    bulk_modulus_error = np.linalg.norm(
        md_bulk_modulus - gt_bulk_modulus
    )  # Error is the L2 norm of deviation from the ground truth value

    md_structure = md_job.read_structure(
    )  # Read relaxed structure after optimization
    error_abc, error_ang = ezff.error_lattice_constant(
        MD=md_structure, GT=gt_structure
    )  # error_abc = error in lattice constants, error_ang = error in lattice angles
    latt_error = np.linalg.norm(error_abc[0])  # error in 'a' lattice constant

    return [latt_error, bulk_modulus_error]
Ejemplo n.º 5
0
def my_error_function(variable_values):
    # Get rank from pool
    try:
        myrank = pool.rank
    except:
        myrank = 0

    # FOR THE RELAXED STRUCTURE
    path = str(myrank) + '/relaxed'
    relaxed_job = gulp.job(path=path)
    relaxed_job.structure = gt_relax_structure
    relaxed_job.forcefield = ezff.generate_forcefield(template,
                                                      variable_values,
                                                      FFtype='SW')
    relaxed_job.options['pbc'] = True
    relaxed_job.options['relax_atoms'] = True
    relaxed_job.options['relax_cell'] = True
    relaxed_job.options['phonon_dispersion'] = True
    relaxed_job.options['phonon_dispersion_from'] = '0 0 0'
    relaxed_job.options['phonon_dispersion_to'] = '0.5 0.5 0'
    # Submit job and read output
    relaxed_job.run()
    # Read output from completed GULP job and cleanup job files
    md_relax_disp_GS = relaxed_job.read_phonon_dispersion()
    md_relaxed_moduli = relaxed_job.read_elastic_moduli()
    md_relaxed_structure = relaxed_job.read_structure()
    relaxed_job.cleanup()  # FINISH RELAXED JOB

    # FOR THE COMPRESSED STRUCTURE
    path = str(myrank) + '/compressed'
    compressed_job = gulp.job(path=path)
    compressed_job.structure = gt_compressed_structure
    compressed_job.forcefield = ezff.generate_forcefield(template,
                                                         variable_values,
                                                         FFtype='SW')
    compressed_job.options['pbc'] = True
    compressed_job.options['relax_atoms'] = True
    compressed_job.options['relax_cell'] = False
    compressed_job.options['phonon_dispersion'] = True
    compressed_job.options['phonon_dispersion_from'] = '0 0 0'
    compressed_job.options['phonon_dispersion_to'] = '0.5 0.5 0'
    # Submit job and read output
    compressed_job.run()
    # Read output from completed GULP job and cleanup job files
    md_compressed_disp_GS = compressed_job.read_phonon_dispersion()
    compressed_job.cleanup()  # FINISH COMPRESSED JOB

    # FOR THE EXPANDED STRUCTURE
    path = str(myrank) + '/expanded'
    expanded_job = gulp.job(path=path)
    expanded_job.structure = gt_expanded_structure
    expanded_job.forcefield = ezff.generate_forcefield(template,
                                                       variable_values,
                                                       FFtype='SW')
    expanded_job.options['pbc'] = True
    expanded_job.options['relax_atoms'] = True
    expanded_job.options['relax_cell'] = False
    expanded_job.options['phonon_dispersion'] = True
    expanded_job.options['phonon_dispersion_from'] = '0 0 0'
    expanded_job.options['phonon_dispersion_to'] = '0.5 0.5 0'
    # Submit job and read output
    expanded_job.run()
    # Read output from completed GULP job and cleanup job files
    md_expanded_disp_GS = expanded_job.read_phonon_dispersion()
    expanded_job.cleanup()  # FINISH EXPANDED JOB

    # Compute 5 errors from the 3 GULP jobs
    error_abc, error_ang = ezff.error_lattice_constant(MD=md_relaxed_structure,
                                                       GT=gt_relax_structure)
    a_lattice_error = np.linalg.norm(
        error_abc[0])  # Error in 'a' lattice constant
    b_lattice_error = np.linalg.norm(
        error_abc[1])  # Error in 'b' lattice constant

    md_c11 = md_relaxed_moduli[0][0, 0] * md_relaxed_structure.box[2, 2] * (
        2.0 / 13.97
    )  # Extracting c11 for a bulk-like layered structure from the monolayer GULP calculation
    modulus_error = np.linalg.norm(md_c11 - gt_c11)

    phon_error_relaxed = ezff.error_phonon_dispersion(MD=md_relax_disp_GS,
                                                      GT=gt_relax_disp_GS,
                                                      weights='acoustic')
    phon_error_expanded = ezff.error_phonon_dispersion(MD=md_expanded_disp_GS,
                                                       GT=gt_expanded_disp_GS,
                                                       weights='acoustic')
    phon_error_compressed = ezff.error_phonon_dispersion(
        MD=md_compressed_disp_GS, GT=gt_compressed_disp_GS, weights='acoustic')

    return [
        a_lattice_error, b_lattice_error, modulus_error, phon_error_relaxed,
        phon_error_compressed, phon_error_expanded
    ]