Пример #1
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def _convert_to_su4(U):
    r"""Check unitarity of a 4x4 matrix and convert it to :math:`SU(4)` if the determinant is not 1.

    Args:
        U (array[complex]): A matrix, presumed to be :math:`4 \times 4` and unitary.

    Returns:
        array[complex]: A :math:`4 \times 4` matrix in :math:`SU(4)` that is
        equivalent to U up to a global phase.
    """
    # Check unitarity
    if not math.allclose(
            math.dot(U, math.T(math.conj(U))), math.eye(4), atol=1e-7):
        raise ValueError("Operator must be unitary.")

    # Compute the determinant
    det = math.linalg.det(U)

    # Convert to SU(4) if it's not close to 1
    if not math.allclose(det, 1.0):
        exp_angle = -1j * math.cast_like(math.angle(det), 1j) / 4
        U = math.cast_like(U, det) * math.exp(exp_angle)

    return U
Пример #2
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def _convert_to_su2(U):
    r"""Check unitarity of a matrix and convert it to :math:`SU(2)` if possible.

    Args:
        U (array[complex]): A matrix, presumed to be :math:`2 \times 2` and unitary.

    Returns:
        array[complex]: A :math:`2 \times 2` matrix in :math:`SU(2)` that is
        equivalent to U up to a global phase.
    """
    # Check unitarity
    if not math.allclose(
            math.dot(U, math.T(math.conj(U))), math.eye(2), atol=1e-7):
        raise ValueError("Operator must be unitary.")

    # Compute the determinant
    det = U[0, 0] * U[1, 1] - U[0, 1] * U[1, 0]

    # Convert to SU(2) if it's not close to 1
    if not math.allclose(det, [1.0]):
        exp_angle = -1j * math.cast_like(math.angle(det), 1j) / 2
        U = math.cast_like(U, exp_angle) * math.exp(exp_angle)

    return U
Пример #3
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def _decomposition_3_cnots(U, wires):
    r"""The most general form of this decomposition is U = (A \otimes B) V (C \otimes D),
    where V is as depicted in the circuit below:
     -╭U- = -C--╭X--RZ(d)--╭C---------╭X--A-
     -╰U- = -D--╰C--RY(b)--╰X--RY(a)--╰C--B-
    """

    # First we add a SWAP as per v1 of arXiv:0308033, which helps with some
    # rearranging of gates in the decomposition (it will cancel out the fact
    # that we need to add a SWAP to fix the determinant in another part later).
    swap_U = np.exp(1j * np.pi / 4) * math.dot(math.cast_like(SWAP, U), U)

    # Choose the rotation angles of RZ, RY in the two-qubit decomposition.
    # They are chosen as per Proposition V.1 in quant-ph/0308033 and are based
    # on the phases of the eigenvalues of :math:`E^\dagger \gamma(U) E`, where
    #    \gamma(U) = (E^\dag U E) (E^\dag U E)^T.
    # The rotation angles can be computed as follows (any three eigenvalues can be used)
    u = math.dot(Edag, math.dot(swap_U, E))
    gammaU = math.dot(u, math.T(u))
    evs, _ = math.linalg.eig(gammaU)

    # We will sort the angles so that results are consistent across interfaces.
    angles = math.sort([math.angle(ev) for ev in evs])

    x, y, z = angles[0], angles[1], angles[2]

    # Compute functions of the eigenvalues; there are different options in v1
    # vs. v3 of the paper, I'm not entirely sure why. This is the version from v3.
    alpha = (x + y) / 2
    beta = (x + z) / 2
    delta = (z + y) / 2

    # This is the interior portion of the decomposition circuit
    interior_decomp = [
        qml.CNOT(wires=[wires[1], wires[0]]),
        qml.RZ(delta, wires=wires[0]),
        qml.RY(beta, wires=wires[1]),
        qml.CNOT(wires=wires),
        qml.RY(alpha, wires=wires[1]),
        qml.CNOT(wires=[wires[1], wires[0]]),
    ]

    # We need the matrix representation of this interior part, V, in order to
    # decompose U = (A \otimes B) V (C \otimes D)
    #
    # Looking at the decomposition above, V has determinant -1 (because there
    # are 3 CNOTs, each with determinant -1). The relationship between U and V
    # requires that both are in SU(4), so we add a SWAP after to V. We will see
    # how this gets fixed later.
    #
    # -╭V- = -╭X--RZ(d)--╭C---------╭X--╭SWAP-
    # -╰V- = -╰C--RY(b)--╰X--RY(a)--╰C--╰SWAP-

    RZd = qml.RZ(math.cast_like(delta, 1j), wires=wires[0]).matrix
    RYb = qml.RY(beta, wires=wires[0]).matrix
    RYa = qml.RY(alpha, wires=wires[0]).matrix

    V_mats = [
        CNOT10,
        math.kron(RZd, RYb), CNOT01,
        math.kron(math.eye(2), RYa), CNOT10, SWAP
    ]

    V = math.convert_like(math.eye(4), U)

    for mat in V_mats:
        V = math.dot(math.cast_like(mat, U), V)

    # Now we need to find the four SU(2) operations A, B, C, D
    A, B, C, D = _extract_su2su2_prefactors(swap_U, V)

    # At this point, we have the following:
    # -╭U-╭SWAP- = --C--╭X-RZ(d)-╭C-------╭X-╭SWAP--A
    # -╰U-╰SWAP- = --D--╰C-RZ(b)-╰X-RY(a)-╰C-╰SWAP--B
    #
    # Using the relationship that SWAP(A \otimes B) SWAP = B \otimes A,
    # -╭U-╭SWAP- = --C--╭X-RZ(d)-╭C-------╭X--B--╭SWAP-
    # -╰U-╰SWAP- = --D--╰C-RZ(b)-╰X-RY(a)-╰C--A--╰SWAP-
    #
    # Now the SWAPs cancel, giving us the desired decomposition
    # (up to a global phase).
    # -╭U- = --C--╭X-RZ(d)-╭C-------╭X--B--
    # -╰U- = --D--╰C-RZ(b)-╰X-RY(a)-╰C--A--

    A_ops = zyz_decomposition(A, wires[1])
    B_ops = zyz_decomposition(B, wires[0])
    C_ops = zyz_decomposition(C, wires[0])
    D_ops = zyz_decomposition(D, wires[1])

    # Return the full decomposition
    return C_ops + D_ops + interior_decomp + A_ops + B_ops
Пример #4
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def _decomposition_2_cnots(U, wires):
    r"""If 2 CNOTs are required, we can write the circuit as
     -╭U- = -A--╭X--RZ(d)--╭X--C-
     -╰U- = -B--╰C--RX(p)--╰C--D-
    We need to find the angles for the Z and X rotations such that the inner
    part has the same spectrum as U, and then we can recover A, B, C, D.
    """
    # Compute the rotation angles
    u = math.dot(Edag, math.dot(U, E))
    gammaU = math.dot(u, math.T(u))
    evs, _ = math.linalg.eig(gammaU)

    # These choices are based on Proposition III.3 of
    # https://arxiv.org/abs/quant-ph/0308045
    # There is, however, a special case where the circuit has the form
    # -╭U- = -A--╭C--╭X--C-
    # -╰U- = -B--╰X--╰C--D-
    #
    # or some variant of this, where the two CNOTs are adjacent.
    #
    # What happens here is that the set of evs is -1, -1, 1, 1 and we can write
    # -╭U- = -A--╭X--SZ--╭X--C-
    # -╰U- = -B--╰C--SX--╰C--D-
    # where SZ and SX are square roots of Z and X respectively. (This
    # decomposition comes from using Hadamards to flip the direction of the
    # first CNOT, and then decomposing them and merging single-qubit gates.) For
    # some reason this case is not handled properly with the full algorithm, so
    # we treat it separately.

    sorted_evs = math.sort(math.real(evs))

    if math.allclose(sorted_evs, [-1, -1, 1, 1]):
        interior_decomp = [
            qml.CNOT(wires=[wires[1], wires[0]]),
            qml.S(wires=wires[0]),
            qml.SX(wires=wires[1]),
            qml.CNOT(wires=[wires[1], wires[0]]),
        ]

        # S \otimes SX
        inner_matrix = S_SX
    else:
        # For the non-special case, the eigenvalues come in conjugate pairs.
        # We need to find two non-conjugate eigenvalues to extract the angles.
        x = math.angle(evs[0])
        y = math.angle(evs[1])

        # If it was the conjugate, grab a different eigenvalue.
        if math.allclose(x, -y):
            y = math.angle(evs[2])

        delta = (x + y) / 2
        phi = (x - y) / 2

        interior_decomp = [
            qml.CNOT(wires=[wires[1], wires[0]]),
            qml.RZ(delta, wires=wires[0]),
            qml.RX(phi, wires=wires[1]),
            qml.CNOT(wires=[wires[1], wires[0]]),
        ]

        RZd = qml.RZ(math.cast_like(delta, 1j), wires=0).matrix
        RXp = qml.RX(phi, wires=0).matrix
        inner_matrix = math.kron(RZd, RXp)

    # We need the matrix representation of this interior part, V, in order to
    # decompose U = (A \otimes B) V (C \otimes D)
    V = math.dot(math.cast_like(CNOT10, U),
                 math.dot(inner_matrix, math.cast_like(CNOT10, U)))

    # Now we find the A, B, C, D in SU(2), and return the decomposition
    A, B, C, D = _extract_su2su2_prefactors(U, V)

    A_ops = zyz_decomposition(A, wires[0])
    B_ops = zyz_decomposition(B, wires[1])
    C_ops = zyz_decomposition(C, wires[0])
    D_ops = zyz_decomposition(D, wires[1])

    return C_ops + D_ops + interior_decomp + A_ops + B_ops
Пример #5
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def test_angle(t):
    """Test that the angle function works for a variety
    of input"""
    res = fn.angle(t)
    assert fn.allequal(res, [0, np.pi / 2, np.pi / 4])
Пример #6
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def zyz_decomposition(U, wire):
    r"""Recover the decomposition of a single-qubit matrix :math:`U` in terms of
    elementary operations.

    Diagonal operations will be converted to a single :class:`.RZ` gate, while non-diagonal
    operations will be converted to a :class:`.Rot` gate that implements the original operation
    up to a global phase in the form :math:`RZ(\omega) RY(\theta) RZ(\phi)`.

    Args:
        U (tensor): A 2 x 2 unitary matrix.
        wire (Union[Wires, Sequence[int] or int]): The wire on which to apply the operation.

    Returns:
        list[qml.Operation]: A ``Rot`` gate on the specified wire that implements ``U``
        up to a global phase, or an equivalent ``RZ`` gate if ``U`` is diagonal.

    **Example**

    Suppose we would like to apply the following unitary operation:

    .. code-block:: python3

        U = np.array([
            [-0.28829348-0.78829734j,  0.30364367+0.45085995j],
            [ 0.53396245-0.10177564j,  0.76279558-0.35024096j]
        ])

    For PennyLane devices that cannot natively implement ``QubitUnitary``, we
    can instead recover a ``Rot`` gate that implements the same operation, up
    to a global phase:

    >>> decomp = zyz_decomposition(U, 0)
    >>> decomp
    [Rot(-0.24209529417800013, 1.14938178234275, 1.7330581433950871, wires=[0])]
    """
    U = _convert_to_su2(U)

    # Check if the matrix is diagonal; only need to check one corner.
    # If it is diagonal, we don't need a full Rot, just return an RZ.
    if math.allclose(U[0, 1], [0.0]):
        omega = 2 * math.angle(U[1, 1])
        return [qml.RZ(omega, wires=wire)]

    # If the top left element is 0, can only use the off-diagonal elements. We
    # have to be very careful with the math here to ensure things that get
    # multiplied together are of the correct type in the different interfaces.
    if math.allclose(U[0, 0], [0.0]):
        phi = 0.0
        theta = -np.pi
        omega = 1j * math.log(U[0, 1] / U[1, 0]) - np.pi
    else:
        # If not diagonal, compute the angle of the RY
        cos2_theta_over_2 = math.abs(U[0, 0] * U[1, 1])
        theta = 2 * math.arccos(math.sqrt(cos2_theta_over_2))

        el_division = U[0, 0] / U[1, 0]
        tan_part = math.cast_like(math.tan(theta / 2), el_division)
        omega = 1j * math.log(tan_part * el_division)
        phi = -omega - math.cast_like(2 * math.angle(U[0, 0]), omega)

    return [
        qml.Rot(math.real(phi), math.real(theta), math.real(omega), wires=wire)
    ]