Пример #1
0
       masses for the atoms (has to have length ``mode.shape[1] // 3``

    Returns
    -------
    numpy.ndarray
        displacements per mode with final dimension ``(mode.shape[0], 3)``, the displacements are in Ang
    """
    if mode.ndim == 1:
        return displacement(mode.reshape(1, -1), hw, mass).reshape(-1, 3)

    return _displacement(mode, hw, mass)


# Electron rest mass in units of proton mass (the units we use for the atoms)
_displacement_const = (2 * units('Ry', 'eV') *
                       constant.m_e('amu'))**0.5 * units('Bohr', 'Ang')


def _displacement(mode, hw, mass):
    """ Real space displacements """
    idx = (hw < 0).nonzero()[0]
    U = mode.copy()
    U[idx, :] = 0.

    # Now create the remaining displacements
    idx = np.delete(_a.arangei(mode.shape[0]), idx)

    # Generate displacement factor
    factor = _displacement_const / hw[idx].reshape(-1, 1)**0.5

    U.shape = (mode.shape[0], -1, 3)
Пример #2
0
    mass : array_like
       masses for the atoms (has to have length ``mode.shape[1] // 3``

    Returns
    -------
    numpy.ndarray
        displacements per mode with final dimension ``(mode.shape[0], 3)``, displacements are in Ang
    """
    if mode.ndim == 1:
        return displacement(mode.reshape(1, -1), hw, mass)[0]

    return _displacement(mode, hw, mass)


# Rest mass in units of proton mass (the units we use for the atoms)
_displacement_const = (2 * units('Ry', 'eV') * constant.m_e('amu')) ** 0.5 * units('Bohr', 'Ang')


def _displacement(mode, hw, mass):
    """ Real space displacements """
    idx = (hw == 0).nonzero()[0]
    U = mode.copy()
    U[idx, :] = 0.

    # Now create the remaining displacements
    idx = delete(_a.arangei(mode.shape[0]), idx)

    # Generate displacement factor
    factor = _displacement_const / fabs(hw[idx]).reshape(-1, 1) ** 0.5

    U.shape = (mode.shape[0], -1, 3)