示例#1
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def test_VCI4_int(inpdata):

    if inpdata is None:
        return 'VCI quadruples intensities'

    VSCF = vib.VSCF2D(inpdata.v1, inpdata.v2)
    VSCF.solve_singles()

    VCI = vib.VCI(VSCF.get_groundstate_wfn(), inpdata.v1, inpdata.v2)
    VCI.generate_states(4)
    VCI.solve()
    VCI.calculate_intensities(inpdata.dm1, inpdata.dm2)

    d = np.abs(VCI.intensities - inpdata.vci4_int).mean()
    return d < 1
示例#2
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def test_VCI4(inpdata):

    if inpdata is None:
        return 'VCI quadruples'

    VSCF = vib.VSCF2D(inpdata.v1, inpdata.v2)
    VSCF.solve_singles()

    VCI = vib.VCI(VSCF.get_groundstate_wfn(), inpdata.v1, inpdata.v2)
    VCI.generate_states(4)
    VCI.solve()

    d = np.abs(VCI.energies - inpdata.vci4).mean()

    return d < 1
示例#3
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# Read in anharmonic 1-mode dipole moments

dm1 = vib.Dipole(grid)
dm1.read_np(os.path.join('potentials', 'Dm1_g16.npy'))

# Read in anharmonic 2-mode potentials

v2 = vib.Potential(grid, order=2)
v2.read_np(os.path.join('potentials', 'V2_g16.npy'))

# Read in anharmonic 2-mode dipole moments

dm2 = vib.Dipole(grid, order=2)
dm2.read_np(os.path.join('potentials', 'Dm2_g16.npy'))

# Run VSCF calculations for these potentials
# Here we solve only for the vibrational ground state

VSCF = vib.VSCF2D(v1, v2)
VSCF.solve()

# Now run VCI calculations using the VSCF wavefunction

VCI = vib.VCI(VSCF.get_groundstate_wfn(), v1, v2)
VCI.generate_states_nmax(4, 4)  # VCI-3
VCI.solve()
VCI.calculate_IR(dm1, dm2)  # calculate intensities

VCI.print_results(maxfreq=10000, which=3)
VCI.print_contributions(maxfreq=10000, which=2)