Exemplo n.º 1
0
def test_transform_two_body_elements():
    l = 10
    u = np.random.random((l, l, l, l)) + 1j * np.random.random((l, l, l, l))
    C = np.random.random((l, l)) + 1j * np.random.random((l, l))

    u_transformed = np.einsum(
        "ls, kr, jq, ip, ijkl -> pqrs",
        C,
        C,
        C.conj(),
        C.conj(),
        u,
        optimize=True,
    )

    np.testing.assert_allclose(
        u_transformed,
        BasisSet.transform_two_body_elements(u, C, np=np),
        atol=1e-10,
    )

    _u = np.dot(u, C)
    _u = np.tensordot(_u, C, axes=(2, 0)).transpose(0, 1, 3, 2)
    _u = np.tensordot(_u, C.conj(), axes=(1, 0)).transpose(0, 3, 1, 2)
    _u = np.tensordot(C.conj().T, _u, axes=(1, 0))

    np.testing.assert_allclose(_u,
                               BasisSet.transform_two_body_elements(u, C, np))
    np.testing.assert_allclose(
        _u, BasisSet.transform_two_body_elements(u, C, np, C_tilde=C.conj().T))
Exemplo n.º 2
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def test_anti_symmetric_properties():
    l_half = 10
    u = np.random.random((l_half, l_half, l_half, l_half))
    # Make u symmetric
    u = u + u.transpose(1, 0, 3, 2)
    u = BasisSet.anti_symmetrize_u(BasisSet.add_spin_two_body(u, np=np))

    np.testing.assert_allclose(u, -u.transpose(0, 1, 3, 2), atol=1e-10)
    np.testing.assert_allclose(u, -u.transpose(1, 0, 2, 3), atol=1e-10)
    np.testing.assert_allclose(u, u.transpose(1, 0, 3, 2), atol=1e-10)
Exemplo n.º 3
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def test_tddw(get_tddw):
    tddw = get_tddw

    h_dw = get_double_well_one_body_elements(
        tddw.l // 2,
        tddw._basis_set.omega,
        tddw._basis_set.mass,
        tddw._basis_set.barrier_strength,
        dtype=np.complex128,
        axis=0,
    )

    epsilon, C_dw = np.linalg.eigh(h_dw)
    C = BasisSet.add_spin_one_body(C_dw, np=np)

    tddw.change_basis(C[:, : tddw.l])

    dip = np.load(os.path.join("tests", "dat", "tddw_dipole_moment.npy"))
    np.testing.assert_allclose(
        np.abs(dip), np.abs(tddw.dipole_moment), atol=1e-10
    )

    h = np.load(os.path.join("tests", "dat", "tddw_h.npy"))
    np.testing.assert_allclose(h, tddw.h, atol=1e-10)

    u = np.load(os.path.join("tests", "dat", "tddw_u.npy"))
    np.testing.assert_allclose(np.abs(u), np.abs(tddw.u), atol=1e-10)

    spf = np.load(os.path.join("tests", "dat", "tddw_spf.npy"))
    np.testing.assert_allclose(np.abs(spf), np.abs(tddw.spf), atol=1e-10)
Exemplo n.º 4
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def test_transform_one_body_elements():
    l = 10
    h = np.random.random((l, l)) + 1j * np.random.random((l, l))
    C = np.random.random((l, l)) + 1j * np.random.random((l, l))

    h_transformed = np.einsum("ip, jq, ij", C.conj(), C, h, optimize=True)

    np.testing.assert_allclose(
        h_transformed,
        BasisSet.transform_one_body_elements(h, C, np=np),
        atol=1e-10,
    )

    _h = np.dot(h, C)
    _h = np.dot(C.conj().T, _h)

    np.testing.assert_allclose(_h,
                               BasisSet.transform_one_body_elements(h, C, np))
    np.testing.assert_allclose(
        _h, BasisSet.transform_one_body_elements(h, C, np, C_tilde=C.conj().T))
Exemplo n.º 5
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def test_add_spin_one_body():
    l_half = 10
    h = np.random.random((l_half, l_half))
    l = l_half * 2
    h_spin = np.zeros((l, l))

    for p in range(l):
        for q in range(l):
            h_spin[p, q] = spin_delta(p, q) * h[p // 2, q // 2]

    np.testing.assert_allclose(h_spin,
                               BasisSet.add_spin_one_body(h, np=np),
                               atol=1e-10)
Exemplo n.º 6
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def test_anti_symmetrize_u():
    l_half = 10
    u = np.random.random((l_half, l_half, l_half, l_half))
    # Make u symmetric
    u = u + u.transpose(1, 0, 3, 2)
    l = l_half * 2
    u_spin = np.zeros((l, l, l, l))

    for p in range(l):
        for q in range(l):
            for r in range(l):
                for s in range(l):
                    u_spin[p, q, r, s] = (spin_delta(p, r) * spin_delta(q, s) *
                                          u[p // 2, q // 2, r // 2, s // 2])
                    u_spin[p, q, r,
                           s] -= (spin_delta(p, s) * spin_delta(q, r) *
                                  u[p // 2, q // 2, s // 2, r // 2])

    np.testing.assert_allclose(
        u_spin,
        BasisSet.anti_symmetrize_u(BasisSet.add_spin_two_body(u, np=np)),
        atol=1e-10,
    )
Exemplo n.º 7
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def setup_basis_set(
    n,
    l,
    s,
    h,
    u,
    dim=3,
    particle_charge=-1,
    np=None,
    includes_spin=False,
    anti_symmetrized_u=False,
    **kwargs,
):

    if np is None:
        import numpy as np

    bs = BasisSet(
        l,
        dim=dim,
        np=np,
        includes_spin=includes_spin,
        anti_symmetrized_u=anti_symmetrized_u,
    )

    bs.h = h
    bs.u = u
    bs.s = s
    bs.particle_charge = particle_charge

    if "position" in kwargs.keys():
        bs.position = kwargs["position"]

    if "momentum" in kwargs.keys():
        bs.momentum = kwargs["momentum"]

    if "nuclear_repulsion_energy" in kwargs.keys():
        bs.nuclear_repulsion_energy = kwargs["nuclear_repulsion_energy"]

    return bs
Exemplo n.º 8
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def test_spin_two_body():
    l_half = 10
    u = np.random.random((l_half, l_half, l_half, l_half))
    l = l_half * 2
    u_spin = np.zeros((l, l, l, l))

    for p in range(l):
        for q in range(l):
            for r in range(l):
                for s in range(l):
                    u_spin[p, q, r, s] = (spin_delta(p, r) * spin_delta(q, s) *
                                          u[p // 2, q // 2, r // 2, s // 2])

    np.testing.assert_allclose(u_spin,
                               BasisSet.add_spin_two_body(u, np=np),
                               atol=1e-10)
Exemplo n.º 9
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def test_change_of_basis():
    # We try to construct a two-dimensional double-well system from a
    # two-dimensional harmonic oscillator system by using the change-of-basis
    # function with C found from diagonalizing the double-well one-body
    # Hamiltonian.
    n = 2
    l = 12
    omega = 1
    mass = 1
    barrier_strength = 3
    radius = 10
    num_grid_points = 401
    axis = 0

    tdho = GeneralOrbitalSystem(
        n,
        TwoDimensionalHarmonicOscillator(
            l, radius, num_grid_points, omega=omega
        ),
    )

    h_dw = get_double_well_one_body_elements(
        l, omega, mass, barrier_strength, dtype=np.complex128, axis=axis
    )

    epsilon, C_dw = np.linalg.eigh(h_dw)
    C = BasisSet.add_spin_one_body(C_dw, np=np)

    tdho.change_basis(C)

    tddw = GeneralOrbitalSystem(
        n,
        TwoDimensionalDoubleWell(
            l,
            radius,
            num_grid_points,
            omega=omega,
            mass=mass,
            barrier_strength=barrier_strength,
            axis=axis,
        ),
    )
    tddw.change_basis(C)

    np.testing.assert_allclose(tdho.u, tddw.u, atol=1e-7)
    np.testing.assert_allclose(tdho.spf, tddw.spf, atol=1e-7)
Exemplo n.º 10
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def test_add_spin_spf():
    spf = (np.arange(15) + 1).reshape(3, 5).T

    n = 3
    n_a = 2
    n_b = n - n_a

    l = 2 * spf.shape[0]
    assert l == 10

    m_a = l // 2 - n_a
    assert m_a == 3

    m_b = l // 2 - n_b
    assert m_b == 4

    new_spf = BasisSet.add_spin_spf(spf, np)

    # Occupied spin-up
    np.testing.assert_allclose(spf[0], new_spf[0])

    np.testing.assert_allclose(spf[1], new_spf[2])

    # Occupied spin-down
    np.testing.assert_allclose(spf[0], new_spf[1])

    # Virtual spin-up
    np.testing.assert_allclose(spf[2], new_spf[4])

    np.testing.assert_allclose(spf[3], new_spf[6])

    np.testing.assert_allclose(spf[4], new_spf[8])

    # Virtual spin-down
    np.testing.assert_allclose(spf[1], new_spf[3])

    np.testing.assert_allclose(spf[2], new_spf[5])

    np.testing.assert_allclose(spf[3], new_spf[7])

    np.testing.assert_allclose(spf[4], new_spf[9])
Exemplo n.º 11
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def construct_pyscf_system_rhf(
    molecule,
    basis="cc-pvdz",
    add_spin=True,
    anti_symmetrize=True,
    np=None,
    verbose=False,
    charge=0,
    cart=False,
    dip=None,
    **kwargs,
):
    """Convenience function setting up a closed-shell atom or a molecule from
    PySCF as a ``QuantumSystem`` in RHF-basis using PySCF's RHF-solver.

    Parameters
    ----------
    molecule : str
        String describing the atom or molecule. This gets passed to PySCF which
        means that we support all the same string options as PySCF.
    basis : str
        String describing the basis set. PySCF determines which options are
        available.
    add_spin : bool
        Whether or not to return a ``SpatialOrbitalSystem`` (``False``) or a
        ``GeneralOrbitalSystem`` (``True``). Default is ``True``.
    anti_symmetrize : bool
        Whether or not to anti-symmetrize the two-body elements in a
        ``GeneralOrbitalSystem``. This only applies if ``add_spin = True``.
        Default is ``True``.
    np : module
        Array- and linear algebra module.
    dip : list
        [position, momentum] f.ex. from Dalton
    Returns
    -------
    SpatialOrbitalSystem, GeneralOrbitalSystem
        Depending on the choice of ``add_spin`` we return a
        ``SpatialOrbitalSystem`` (``add_spin = False``), or a
        ``GeneralOrbitalSystem`` (``add_spin = True``).

    See Also
    -------
    PySCF

    Example
    -------
    >>> # Set up the Beryllium atom centered at (0, 0, 0)
    >>> system = construct_pyscf_system_rhf(
    ...     "be 0 0 0", basis="cc-pVDZ", add_spin=False
    ... ) # doctest.ELLIPSIS
    converged SCF energy = -14.5723...
    >>> # Compare the number of occupied basis functions
    >>> system.n == 4 // 2
    True
    >>> gos = system.construct_general_orbital_system()
    >>> gos.n == 4
    True
    >>> system = construct_pyscf_system_rhf(
    ...     "be 0 0 0", basis="cc-pVDZ"
    ... ) # doctest.ELLIPSIS
    converged SCF energy = -14.5723...
    >>> system.n == gos.n
    True
    """

    import pyscf

    if np is None:
        import numpy as np

    # Build molecule in AO-basis
    mol = pyscf.gto.Mole()
    mol.unit = "bohr"
    mol.charge = charge
    mol.cart = cart
    mol.build(atom=molecule, basis=basis, **kwargs)
    nuclear_repulsion_energy = mol.energy_nuc()

    n = mol.nelectron
    assert (
        n %
        2 == 0), "We require closed shell, with an even number of particles"

    l = mol.nao

    hf = pyscf.scf.RHF(mol)
    hf_energy = hf.kernel()

    if not hf.converged:
        warnings.warn("RHF calculation did not converge")

    if verbose:
        print(f"RHF energy: {hf.e_tot}")

    charges = mol.atom_charges()
    coords = mol.atom_coords()
    nuc_charge_center = np.einsum("z,zx->x", charges, coords) / charges.sum()
    mol.set_common_orig_(nuc_charge_center)

    C = np.asarray(hf.mo_coeff)

    h = pyscf.scf.hf.get_hcore(mol)
    s = mol.intor_symmetric("int1e_ovlp")
    u = mol.intor("int2e").reshape(l, l, l, l).transpose(0, 2, 1, 3)
    position = mol.intor("int1e_r").reshape(3, l, l)
    momentum = -1j * mol.intor("int1e_ipovlp").reshape(3, l, l)

    if dip is not None:
        diplen = dip[0]
        arr_eq0 = np.allclose(diplen[0], position[0])
        arr_eq1 = np.allclose(diplen[1], position[1])
        arr_eq2 = np.allclose(diplen[2], position[2])
        if not (arr_eq0 and arr_eq1 and arr_eq2):
            print('WARNING:')
            print('dipole_array_pyscf != dipole_array_dalton')

    bs = BasisSet(l, dim=3, np=np)
    bs.h = h
    bs.s = s
    bs.u = u
    bs.nuclear_repulsion_energy = nuclear_repulsion_energy
    bs.particle_charge = -1
    bs.position = position
    bs.momentum = momentum
    if dip is not None:
        bs.momentum = dip[1]
    bs.change_module(np=np)

    system = SpatialOrbitalSystem(n, bs)
    system.change_basis(C)

    return (system.construct_general_orbital_system(
        anti_symmetrize=anti_symmetrize) if add_spin else system)
Exemplo n.º 12
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def construct_pyscf_system_ao(
    molecule,
    basis="cc-pvdz",
    add_spin=True,
    anti_symmetrize=True,
    np=None,
    **kwargs,
):
    """Convenience function setting up an atom or a molecule from PySCF as a
    ``QuantumSystem``.

    Parameters
    ----------
    molecule : str
        String describing the atom or molecule. This gets passed to PySCF which
        means that we support all the same string options as PySCF.
    basis : str
        String describing the basis set. PySCF determines which options are
        available.
    add_spin : bool
        Whether or not to return a ``SpatialOrbitalSystem`` (``False``) or a
        ``GeneralOrbitalSystem`` (``True``). Default is ``True``.
    anti_symmetrize : bool
        Whether or not to anti-symmetrize the two-body elements in a
        ``GeneralOrbitalSystem``. This only applies if ``add_spin = True``.
        Default is ``True``.
    np : module
        Array- and linear algebra module.

    Returns
    -------
    SpatialOrbitalSystem, GeneralOrbitalSystem
        Depending on the choice of ``add_spin`` we return a
        ``SpatialOrbitalSystem`` (``add_spin = False``), or a
        ``GeneralOrbitalSystem`` (``add_spin = True``).

    See Also
    -------
    PySCF

    Example
    -------
    >>> # Set up the Beryllium atom centered at (0, 0, 0)
    >>> system = construct_pyscf_system_ao(
    ...     "be 0 0 0", basis="cc-pVDZ", add_spin=False
    ... )
    >>> # Compare the number of occupied basis functions
    >>> system.n == 4 // 2
    True
    >>> gos = system.construct_general_orbital_system()
    >>> gos.n == 4
    True
    """

    import pyscf

    if np is None:
        import numpy as np

    mol = pyscf.gto.Mole()
    mol.unit = "bohr"
    mol.build(atom=molecule, basis=basis, **kwargs)
    nuclear_repulsion_energy = mol.energy_nuc()

    n = mol.nelectron
    l = mol.nao

    # n_a = (mol.nelectron + mol.spin) // 2
    # n_b = n_a - mol.spin

    # assert n_b == n - n_a

    h = pyscf.scf.hf.get_hcore(mol)
    s = mol.intor_symmetric("int1e_ovlp")
    u = mol.intor("int2e").reshape(l, l, l, l).transpose(0, 2, 1, 3)
    position = mol.intor("int1e_r").reshape(3, l, l)

    bs = BasisSet(l, dim=3, np=np)
    bs.h = h
    bs.s = s
    bs.u = u
    bs.nuclear_repulsion_energy = nuclear_repulsion_energy
    bs.particle_charge = -1
    bs.position = position
    bs.change_module(np=np)

    system = SpatialOrbitalSystem(n, bs)

    return (system.construct_general_orbital_system(
        anti_symmetrize=anti_symmetrize) if add_spin else system)
Exemplo n.º 13
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def test_antisymmetric_two_body_elements(u):
    l = len(u)
    _u = BasisSet.anti_symmetrize_u(
        BasisSet.add_spin_two_body(get_coulomb_elements(l // 2), np=np))

    np.testing.assert_allclose(u, _u, atol=1e-6, rtol=1e-6)
Exemplo n.º 14
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def test_antisymmetric_one_body_elements(h):
    l = len(h)
    _h = BasisSet.add_spin_one_body(get_one_body_elements(l // 2), np=np)

    np.testing.assert_allclose(h, _h, atol=1e-6, rtol=1e-6)