# This code is part of a Qiskit project.
#
# (C) Copyright IBM 2022, 2023.
#
# This code is licensed under the Apache License, Version 2.0. You may
# obtain a copy of this license in the LICENSE.txt file in the root directory
# of this source tree or at http://www.apache.org/licenses/LICENSE-2.0.
#
# Any modifications or derivative works of this code must retain this
# copyright notice, and modified files need to carry a notice indicating
# that they have been altered from the originals.
"""A container class for electronic operator coefficients (a.k.a. electronic integrals)."""
from __future__ import annotations
from collections.abc import Callable
from numbers import Number
from typing import Optional, Sequence, Tuple, cast
import numpy as np
from qiskit.quantum_info.operators.mixins import LinearMixin
from qiskit_nature.exceptions import QiskitNatureError
import qiskit_nature.optionals as _optionals
from .polynomial_tensor import PolynomialTensor
from .symmetric_two_body import SymmetricTwoBodyIntegrals
from .tensor import Tensor
from .tensor_ordering import (
IndexType,
find_index_order,
to_physicist_ordering,
)
if _optionals.HAS_SPARSE:
# pylint: disable=import-error
from sparse import SparseArray
else:
class SparseArray: # type: ignore
"""Empty SparseArray class
Replacement if sparse.SparseArray is not present.
"""
pass
[ドキュメント]class ElectronicIntegrals(LinearMixin):
r"""A container class for electronic operator coefficients (a.k.a. electronic integrals).
This class contains multiple :class:`qiskit_nature.second_q.operators.PolynomialTensor`
instances, dealing with the specific case of storing electronic integrals, where the up- and
down-spin electronic interactions need to be handled separately. These two spins are also
commonly referred to by :math:`\alpha` and :math:`\beta`, respectively.
Specifically, this class stores three :class:`~.PolynomialTensor` instances:
- :attr:`alpha`: which stores the up-spin integrals
- :attr:`beta`: which stores the down-spin integrals
- :attr:`beta_alpha`: which stores beta-alpha-spin two-body integrals
These tensors are subject to some expectations, namely:
- for ``alpha`` and ``beta`` only the following keys are allowed: ``""``, ``"+-"``, ``"++--"``
- for ``beta_alpha`` the only allowed key is ``"++--"``
- the reported ``register_length`` attributes of all non-empty tensors must match
There are two ways of constructing the ``ElectronicIntegrals``:
.. code-block:: python
# assuming you already have your one- and two-body integrals from somewhere
h1_a, h2_aa, h1_b, h2_bb, h2_ba = ...
from qiskit_nature.second_q.operators import ElectronicIntegrals, PolynomialTensor
alpha = PolynomialTensor({"+-": h1_a, "++--": h2_aa})
beta = PolynomialTensor({"+-": h1_b, "++--": h2_bb})
beta_alpha = PolynomialTensor({"++--": h2_ba})
integrals = ElectronicIntegrals(alpha, beta, beta_alpha)
# alternatively, the following achieves the same effect:
integrals = ElectronicIntegrals.from_raw_integrals(h1_a, h2_aa, h1_b, h2_bb, h2_ba)
This class then exposes common mathematical operations performed on these tensors allowing
simple manipulation of the underlying data structures.
.. code-block:: python
# addition
integrals + integrals
# scalar multiplication
2.0 * integrals
This class will substitute empty ``beta`` and ``beta_alpha`` tensors with the ``alpha`` tensor
when necessary. For example, this means the following will happen:
.. code-block:: python
integrals_pure = ElectronicIntegrals(alpha)
integrals_mixed = ElectronicIntegrals(alpha, beta, beta_alpha)
sum = integrals_pure + integrals_mixed
print(sum.beta.is_empty()) # False
print(sum.beta_alpha.is_empty()) # False
print(sum.beta.equiv(alpha + beta)) # True
print(sum.beta_alpha.equiv(alpha + beta_alpha)) # True
The same logic holds for other mathematical operations involving multiple ``ElectronicIntegrals``.
You can add a custom offset to be included in the operator generated from these coefficients
like so:
.. code-block:: python
from qiskit_nature.second_q.operators import PolynomialTensor
integrals: ElectronicIntegrals
offset = 2.5
integrals.alpha += PolynomialTensor({"": offset})
"""
_VALID_KEYS = {"", "+-", "++--"}
def __init__(
self,
alpha: PolynomialTensor | None = None,
beta: PolynomialTensor | None = None,
beta_alpha: PolynomialTensor | None = None,
*,
validate: bool = True,
) -> None:
"""
Any ``None``-valued argument will internally be replaced by an empty :class:`~.PolynomialTensor`
(see also :meth:`qiskit_nature.second_q.operators.PolynomialTensor.empty`).
Args:
alpha: the up-spin electronic integrals
beta: the down-spin electronic integrals
beta_alpha: the beta-alpha-spin two-body electronic integrals. This may *only* contain
the ``++--`` key.
validate: when set to False, no validation will be performed. Disable this setting with
care!
Raises:
KeyError: if the ``alpha`` tensor contains keys other than ``""``, ``"+-"``, and ``"++--"``.
KeyError: if the ``beta`` tensor contains keys other than ``""``, ``"+-"``, and ``"++--"``.
KeyError: if the ``beta_alpha`` tensor contains keys other than ``"++--"``.
ValueError: if the reported :attr:`~.PolynomialTensor.register_length` attributes of the
alpha-, beta-, and beta-alpha-spin tensors do not all match.
"""
self.alpha = alpha
self.beta = beta
self.beta_alpha = beta_alpha
if validate:
self._validate()
def _validate(self):
"""Performs internal validation."""
self._validate_tensor_keys()
self._validate_register_lengths()
def _validate_tensor_keys(self):
"""Validates the keys of all internal tensors."""
if not self.alpha.keys() <= ElectronicIntegrals._VALID_KEYS:
raise KeyError(
"The only allowed keys for the alpha-spin tensor are '', '+-', and '++--', but your"
f" tensor has keys: {self.alpha.keys()}"
)
if not self.beta.keys() <= ElectronicIntegrals._VALID_KEYS:
raise KeyError(
"The only allowed keys for the beta-spin tensor are '', '+-', and '++--', but your"
f" tensor has keys: {self.beta.keys()}"
)
if not self.beta_alpha.keys() <= {"++--"}:
raise KeyError(
"The only allowed key for the beta-alpha-spin tensor is '++--', but your "
f" tensor has keys: {self.beta_alpha.keys()}"
)
def _validate_register_lengths(self):
"""Validates the reported `register_length` attributes of all internal tensors."""
alpha_len = self.alpha.register_length
beta_len = self.beta.register_length
beta_alpha_len = self.beta_alpha.register_length
if alpha_len is None:
if beta_len is not None:
raise ValueError(
f"The reported register_length of your beta-spin tensor, {beta_len}, does not "
f"match the alpha-spin tensor one, {alpha_len}."
)
if beta_alpha_len is not None:
raise ValueError(
f"The reported register_length of your beta-alpha-spin tensor, {beta_alpha_len}"
f", does not match the alpha-spin tensor one, {alpha_len}."
)
else:
if beta_len is not None and alpha_len != beta_len:
raise ValueError(
f"The reported register_length of your beta-spin tensor, {beta_len}, does not "
f"match the alpha-spin tensor one, {alpha_len}."
)
if beta_alpha_len is not None and alpha_len != beta_alpha_len:
raise ValueError(
f"The reported register_length of your beta-alpha-spin tensor, {beta_alpha_len}"
f", does not match the alpha-spin tensor one, {alpha_len}."
)
@property
def alpha(self) -> PolynomialTensor:
"""The up-spin electronic integrals."""
return self._alpha
@alpha.setter
def alpha(self, alpha: PolynomialTensor | None) -> None:
self._alpha = alpha if alpha is not None else PolynomialTensor.empty()
@property
def beta(self) -> PolynomialTensor:
"""The down-spin electronic integrals."""
return self._beta
@beta.setter
def beta(self, beta: PolynomialTensor | None) -> None:
self._beta = beta if beta is not None else PolynomialTensor.empty()
@property
def beta_alpha(self) -> PolynomialTensor:
"""The beta-alpha-spin two-body electronic integrals."""
return self._beta_alpha
@beta_alpha.setter
def beta_alpha(self, beta_alpha: PolynomialTensor | None) -> None:
if beta_alpha is None:
self._beta_alpha = PolynomialTensor.empty()
else:
keys = set(beta_alpha)
if keys and keys != {"++--"}:
raise ValueError(
f"The beta_alpha tensor may only contain a `++--` key, not {keys}."
)
self._beta_alpha = beta_alpha
@property
def alpha_beta(self) -> PolynomialTensor:
"""The alpha-beta-spin two-body electronic integrals.
These get reconstructed from :attr:`beta_alpha` by transposing in the physicist' ordering
convention.
"""
if self.beta_alpha.is_empty():
return self.beta_alpha
two_body_ba = self.beta_alpha["++--"]
if isinstance(two_body_ba, SymmetricTwoBodyIntegrals):
# NOTE: to ensure proper inter-operability with the symmetry-aware integral containers,
# we delegate the conjugation to the objects themselves
return PolynomialTensor({"++--": two_body_ba.conjugate()}, validate=False)
alpha_beta = cast(Tensor, np.moveaxis(two_body_ba, (0, 1), (2, 3)))
return PolynomialTensor({"++--": alpha_beta}, validate=False)
@property
def one_body(self) -> ElectronicIntegrals:
"""Returns only the one-body integrals."""
alpha: PolynomialTensor = None
if "+-" in self.alpha:
alpha = PolynomialTensor(
{"+-": self.alpha["+-"]},
validate=False,
)
beta: PolynomialTensor = None
if "+-" in self.beta:
beta = PolynomialTensor(
{"+-": self.beta["+-"]},
validate=False,
)
return self.__class__(alpha, beta)
@property
def two_body(self) -> ElectronicIntegrals:
"""Returns only the two-body integrals."""
alpha: PolynomialTensor = None
if "++--" in self.alpha:
alpha = PolynomialTensor(
{"++--": self.alpha["++--"]},
validate=False,
)
beta: PolynomialTensor = None
if "++--" in self.beta:
beta = PolynomialTensor(
{"++--": self.beta["++--"]},
validate=False,
)
beta_alpha: PolynomialTensor = None
if "++--" in self.beta_alpha:
beta_alpha = PolynomialTensor(
{"++--": self.beta_alpha["++--"]},
validate=False,
)
return self.__class__(alpha, beta, beta_alpha)
@property
def register_length(self) -> int | None:
"""The size of the operator that can be generated from these `ElectronicIntegrals`."""
alpha_length = self.alpha.register_length
return alpha_length
def __eq__(self, other: object) -> bool:
"""Check equality of first ElectronicIntegrals with other
Args:
other: second ``ElectronicIntegrals`` object to be compared with the first.
Returns:
True when ``ElectronicIntegrals`` objects are equal, False when unequal.
"""
if not isinstance(other, ElectronicIntegrals):
return False
if (
self.alpha == other.alpha
and self.beta == other.beta
and self.beta_alpha == other.beta_alpha
):
return True
return False
[ドキュメント] def equiv(self, other: object) -> bool:
"""Check equivalence of first ElectronicIntegrals with other
Args:
other: second ``ElectronicIntegrals`` object to be compared with the first.
Returns:
True when ``ElectronicIntegrals`` objects are equivalent, False when not.
"""
if not isinstance(other, ElectronicIntegrals):
return False
if (
self.alpha.equiv(other.alpha)
and self.beta.equiv(other.beta)
and self.beta_alpha.equiv(other.beta_alpha)
):
return True
return False
def _multiply(self, other: complex) -> ElectronicIntegrals:
if not isinstance(other, Number):
raise TypeError(f"other {other} must be a number")
return self.__class__(
cast(PolynomialTensor, other * self.alpha),
cast(PolynomialTensor, other * self.beta),
cast(PolynomialTensor, other * self.beta_alpha),
)
def _add(self, other: ElectronicIntegrals, qargs=None) -> ElectronicIntegrals:
if not isinstance(other, ElectronicIntegrals):
raise TypeError("Incorrect argument type: other should be ElectronicIntegrals")
# we need to handle beta separately in order to inject alpha where necessary
beta: PolynomialTensor = None
beta_self_empty = self.beta.is_empty()
beta_other_empty = other.beta.is_empty()
if not (beta_self_empty and beta_other_empty):
beta_self = self.alpha if beta_self_empty else self.beta
beta_other = other.alpha if beta_other_empty else other.beta
beta = beta_self + beta_other
return self.__class__(
self.alpha + other.alpha,
beta,
self.beta_alpha + other.beta_alpha,
)
[ドキュメント] @classmethod
def apply(
cls,
function: Callable[..., np.ndarray | SparseArray | complex],
*operands: ElectronicIntegrals,
multi: bool = False,
validate: bool = True,
) -> ElectronicIntegrals | list[ElectronicIntegrals]:
"""Exposes the :meth:`qiskit_nature.second_q.operators.PolynomialTensor.apply` method.
This behaves identical to the ``apply`` implementation of the ``PolynomialTensor``, applied
to the :attr:`alpha`, :attr:`beta`, and :attr:`beta_alpha` attributes of the provided
``ElectronicIntegrals`` operands.
This method is special, because it handles the scenario in which any operand has a non-empty
:attr:`beta` attribute, in which case the empty-beta attributes of any other operands will
be filled with :attr:`alpha` attributes of those operands.
The :attr:`beta_alpha` attributes will only be handled if they are non-empty in all supplied
operands.
Args:
function: the function to apply to the internal arrays of the provided operands. This
function must take numpy (or sparse) arrays as its positional arguments. The number
of arguments must match the number of provided operands.
operands: a sequence of ``ElectronicIntegrals`` instances on which to operate.
multi: when set to True this indicates that the provided numpy function will return
multiple new numpy arrays which will each be wrapped into an ``ElectronicIntegrals``
instance separately.
validate: when set to False, no validation will be performed. Disable this setting with
care!
Returns:
A new ``ElectronicIntegrals``.
"""
alphas = PolynomialTensor.apply(
function, *(op.alpha for op in operands), multi=multi, validate=validate
)
betas: PolynomialTensor | list[PolynomialTensor] | None = None
if any(not op.beta.is_empty() for op in operands):
# If any beta-entry is non-empty, we have to perform this computation.
# Empty tensors will be populated with their alpha-terms automatically.
betas = PolynomialTensor.apply(
function,
*(op.alpha if op.beta.is_empty() else op.beta for op in operands),
multi=multi,
validate=validate,
)
beta_alphas: PolynomialTensor | list[PolynomialTensor] | None = None
if all(not op.beta_alpha.is_empty() for op in operands):
# We can only perform this operation, when all beta_alpha tensors are non-empty.
beta_alphas = PolynomialTensor.apply(
function, *(op.beta_alpha for op in operands), multi=multi, validate=validate
)
if multi:
if betas is None:
betas = [None] * len(alphas)
if beta_alphas is None:
beta_alphas = [None] * len(alphas)
return [
cls(a, b, ba, validate=validate) for a, b, ba in zip(alphas, betas, beta_alphas)
]
alphas = cast(PolynomialTensor, alphas)
betas = cast(Optional[PolynomialTensor], betas)
beta_alphas = cast(Optional[PolynomialTensor], beta_alphas)
return cls(alphas, betas, beta_alphas, validate=validate)
[ドキュメント] @classmethod
def stack(
cls,
function: Callable[..., np.ndarray | SparseArray | Number],
operands: Sequence[ElectronicIntegrals],
*,
validate: bool = True,
) -> ElectronicIntegrals:
"""Exposes the :meth:`qiskit_nature.second_q.operators.PolynomialTensor.stack` method.
This behaves identical to the ``stack`` implementation of the ``PolynomialTensor``, applied
to the :attr:`alpha`, :attr:`beta`, and :attr:`beta_alpha` attributes of the provided
``ElectronicIntegrals`` operands.
This method is special, because it handles the scenario in which any operand has a non-empty
:attr:`beta` attribute, in which case the empty-beta attributes of any other operands will
be filled with :attr:`alpha` attributes of those operands.
The :attr:`beta_alpha` attributes will only be handled if they are non-empty in all supplied
operands.
.. note::
When stacking arrays this will likely lead to array shapes which would fail the shape
validation check. This is considered an advanced use case which is why the user is left
to disable this check themselves, to ensure they know what they are doing.
Args:
function: the stacking function to apply to the internal arrays of the provided
operands. This function must take a sequence of numpy (or sparse) arrays as its
first argument. You should use :code:`functools.partial` if you need to provide
keyword arguments (e.g. :code:`partial(np.stack, axis=-1)`). Common methods to use
here are :func:`numpy.hstack` and :func:`numpy.vstack`.
operands: a sequence of ``ElectronicIntegrals`` instances on which to operate.
validate: when set to False, no validation will be performed. Disable this setting with
care!
Returns:
A new ``ElectronicIntegrals``.
"""
alpha = PolynomialTensor.stack(function, [op.alpha for op in operands], validate=validate)
beta: PolynomialTensor = None
if any(not op.beta.is_empty() for op in operands):
# If any beta-entry is non-empty, we have to perform this computation.
# Empty tensors will be populated with their alpha-terms automatically.
beta = PolynomialTensor.stack(
function,
[op.alpha if op.beta.is_empty() else op.beta for op in operands],
validate=validate,
)
beta_alpha: PolynomialTensor = None
if all(not op.beta_alpha.is_empty() for op in operands):
# We can only perform this operation, when all beta_alpha tensors are non-empty.
beta_alpha = PolynomialTensor.stack(
function, [op.beta_alpha for op in operands], validate=validate
)
return cls(alpha, beta, beta_alpha, validate=validate)
[ドキュメント] def split(
self,
function: Callable[..., np.ndarray | SparseArray | Number],
indices_or_sections: int | Sequence[int],
*,
validate: bool = True,
) -> list[ElectronicIntegrals]:
"""Exposes the :meth:`qiskit_nature.second_q.operators.PolynomialTensor.split` method.
This behaves identical to the ``split`` implementation of the ``PolynomialTensor``, applied
to the :attr:`alpha`, :attr:`beta`, and :attr:`beta_alpha` attributes of the provided
``ElectronicIntegrals`` operands.
.. note::
When splitting arrays this will likely lead to array shapes which would fail the shape
validation check. This is considered an advanced use case which is why the user is left
to disable this check themselves, to ensure they know what they are doing.
Args:
function: the splitting function to use. This function must take a single numpy (or
sparse) array as its first input followed by a sequence of indices to split on.
You should use :code:`functools.partial` if you need to provide keyword arguments
(e.g. :code:`partial(np.split, axis=-1)`). Common methods to use here are
:func:`numpy.hsplit` and :func:`numpy.vsplit`.
indices_or_sections: a single index or sequence of indices to split on.
validate: when set to False, no validation will be performed. Disable this setting with
care!
Returns:
The new ``ElectronicIntegrals`` instances.
"""
alphas = self.alpha.split(function, indices_or_sections, validate=validate)
betas: list[PolynomialTensor | None]
if self.beta.is_empty():
betas = [None] * len(alphas)
else:
betas = self.beta.split(function, indices_or_sections, validate=validate)
beta_alphas: list[PolynomialTensor | None]
if self.beta_alpha.is_empty():
beta_alphas = [None] * len(alphas)
else:
beta_alphas = self.beta_alpha.split(function, indices_or_sections, validate=validate)
return [
self.__class__(a, b, ba, validate=validate)
for a, b, ba in zip(alphas, betas, beta_alphas)
]
[ドキュメント] @classmethod
def einsum(
cls,
einsum_map: dict[str, tuple[str, ...]],
*operands: ElectronicIntegrals,
validate: bool = True,
) -> ElectronicIntegrals:
"""Exposes the :meth:`qiskit_nature.second_q.operators.PolynomialTensor.einsum` method.
This behaves identical to the ``einsum`` implementation of the ``PolynomialTensor``, applied
to the :attr:`alpha`, :attr:`beta`, and :attr:`beta_alpha` attributes of the provided
``ElectronicIntegrals`` operands.
This method is special, because it handles the scenario in which any operand has a non-empty
:attr:`beta` attribute, in which case the empty-beta attributes of any other operands will
be filled with :attr:`alpha` attributes of those operands.
The :attr:`beta_alpha` attributes will only be handled if they are non-empty in all supplied
operands.
Args:
einsum_map: a dictionary, mapping from :meth:`numpy.einsum` subscripts to a tuple of
strings. These strings correspond to the keys of matrices to be extracted from the
provided ``ElectronicIntegrals`` operands. The last string in this tuple indicates
the key under which to store the result in the returned ``ElectronicIntegrals``.
operands: a sequence of ``ElectronicIntegrals`` instances on which to operate.
validate: when set to False, no validation will be performed. Disable this setting with
care!
Returns:
A new ``ElectronicIntegrals``.
"""
alpha = PolynomialTensor.einsum(
einsum_map, *(op.alpha for op in operands), validate=validate
)
beta: PolynomialTensor = None
if any(not op.beta.is_empty() for op in operands):
# If any beta-entry is non-empty, we have to perform this computation.
# Empty tensors will be populated with their alpha-terms automatically.
beta = PolynomialTensor.einsum(
einsum_map,
*(op.alpha if op.beta.is_empty() else op.beta for op in operands),
validate=validate,
)
beta_alpha: PolynomialTensor = None
if all(not op.beta_alpha.is_empty() for op in operands):
# We can only perform this operation, when all beta_alpha tensors are non-empty.
beta_alpha = PolynomialTensor.einsum(
einsum_map, *(op.beta_alpha for op in operands), validate=validate
)
return cls(alpha, beta, beta_alpha, validate=validate)
# pylint: disable=invalid-name
[ドキュメント] @classmethod
def from_raw_integrals(
cls,
h1_a: np.ndarray | SparseArray,
h2_aa: np.ndarray | SparseArray | None = None,
h1_b: np.ndarray | SparseArray | None = None,
h2_bb: np.ndarray | SparseArray | None = None,
h2_ba: np.ndarray | SparseArray | None = None,
*,
validate: bool = True,
auto_index_order: bool = True,
) -> ElectronicIntegrals:
"""Loads the provided integral matrices into an ``ElectronicIntegrals`` instance.
When ``auto_index_order`` is enabled,
:meth:`qiskit_nature.second_q.operators.tensor_ordering.find_index_order` will be used to
determine the index ordering of the ``h2_aa`` matrix, based on which the two-body matrices
will automatically be transformed to the physicist' order, which is required by the
:class:`qiskit_nature.second_q.operators.PolynomialTensor`.
Args:
h1_a: the alpha-spin one-body integrals.
h2_aa: the alpha-alpha-spin two-body integrals.
h1_b: the beta-spin one-body integrals.
h2_bb: the beta-beta-spin two-body integrals.
h2_ba: the beta-alpha-spin two-body integrals.
validate: whether or not to validate the integral matrices. Disable this setting with
care!
auto_index_order: whether or not to automatically convert the matrices to physicists'
order.
Raises:
QiskitNatureError: if `auto_index_order=True`, upon encountering an invalid
:class:`qiskit_nature.second_q.operators.tensor_ordering.IndexType`.
Returns:
The resulting ``ElectronicIntegrals``.
"""
alpha_dict = {"+-": h1_a}
if h2_aa is not None:
if auto_index_order and not isinstance(h2_aa, SymmetricTwoBodyIntegrals):
index_order = find_index_order(h2_aa)
if index_order == IndexType.UNKNOWN:
raise QiskitNatureError(
f"The index ordering of the `h2_aa` argument, {index_order}, is invalid.\n"
"Provide the two-body matrices in either chemists' or physicists' order, "
"or disable the automatic transformation to enforce these matrices to be "
"used (`auto_index_order=False`)."
)
h2_aa = to_physicist_ordering(h2_aa, index_order=index_order)
if h2_bb is not None:
h2_bb = to_physicist_ordering(h2_bb, index_order=index_order)
if h2_ba is not None:
h2_ba = to_physicist_ordering(h2_ba, index_order=index_order)
alpha_dict["++--"] = h2_aa
alpha = PolynomialTensor(alpha_dict, validate=validate)
beta = None
beta_dict = {}
if h1_b is not None:
beta_dict["+-"] = h1_b
if h2_bb is not None:
beta_dict["++--"] = h2_bb
if beta_dict:
beta = PolynomialTensor(beta_dict, validate=validate)
beta_alpha = None
if h2_ba is not None:
beta_alpha = PolynomialTensor({"++--": h2_ba}, validate=validate)
return cls(alpha, beta, beta_alpha, validate=validate)
[ドキュメント] def second_q_coeffs(self) -> PolynomialTensor:
"""Constructs the total ``PolynomialTensor`` contained the second-quantized coefficients.
This function constructs the spin-orbital basis tensor as a
:class:`qiskit_nature.second_q.operators.PolynomialTensor`, by arranging the :attr:`alpha`
and :attr:`beta` attributes in a block-ordered fashion (up-spin integrals cover the first
part, down-spin integrals the second part of the resulting register space).
If the :attr:`beta` and/or :attr:`beta_alpha` attributes are empty, the :attr:`alpha` data
will be used in their place.
Returns:
The ``PolynomialTensor`` representing the entire system.
"""
beta_empty = self.beta.is_empty()
beta_alpha_empty = self.beta_alpha.is_empty()
kron_one_body = np.zeros((2, 2))
kron_two_body = np.zeros((2, 2, 2, 2))
kron_tensor = PolynomialTensor({"": 1.0, "+-": kron_one_body, "++--": kron_two_body})
ba_index = (1, 0, 0, 1)
ab_index = (0, 1, 1, 0)
if beta_empty and beta_alpha_empty:
kron_one_body[(0, 0)] = 1
kron_one_body[(1, 1)] = 1
kron_two_body[(0, 0, 0, 0)] = 0.5
kron_two_body[(1, 1, 1, 1)] = 0.5
aa_tensor = self.alpha.get("++--", None)
if aa_tensor is not None:
if not isinstance(aa_tensor, Tensor):
aa_tensor = Tensor(aa_tensor)
ba_index = cast(
Tuple[int, int, int, int], tuple(aa_tensor._reverse_label_template(ba_index))
)
ab_index = cast(
Tuple[int, int, int, int], tuple(aa_tensor._reverse_label_template(ab_index))
)
kron_two_body[ba_index] = 0.5
kron_two_body[ab_index] = 0.5
tensor_blocked_spin_orbitals = PolynomialTensor.apply(np.kron, kron_tensor, self.alpha)
return cast(PolynomialTensor, tensor_blocked_spin_orbitals)
tensor_blocked_spin_orbitals = PolynomialTensor({})
# pure alpha spin
kron_one_body[(0, 0)] = 1
kron_two_body[(0, 0, 0, 0)] = 0.5
tensor_blocked_spin_orbitals += PolynomialTensor.apply(np.kron, kron_tensor, self.alpha)
kron_one_body[(0, 0)] = 0
kron_two_body[(0, 0, 0, 0)] = 0
# pure beta spin
kron_one_body[(1, 1)] = 1
kron_two_body[(1, 1, 1, 1)] = 0.5
tensor_blocked_spin_orbitals += PolynomialTensor.apply(np.kron, kron_tensor, self.beta)
kron_one_body[(1, 1)] = 0
kron_two_body[(1, 1, 1, 1)] = 0
# beta_alpha spin
if not beta_alpha_empty:
kron_tensor = PolynomialTensor({"++--": kron_two_body})
ba_tensor = self.beta_alpha["++--"]
if not isinstance(ba_tensor, Tensor):
ba_tensor = Tensor(ba_tensor)
ba_index = cast(
Tuple[int, int, int, int], tuple(ba_tensor._reverse_label_template(ba_index))
)
ab_index = cast(
Tuple[int, int, int, int], tuple(ba_tensor._reverse_label_template(ab_index))
)
kron_two_body[ba_index] = 0.5
tensor_blocked_spin_orbitals += PolynomialTensor.apply(
np.kron, kron_tensor, self.beta_alpha
)
kron_two_body[ba_index] = 0
# extract transposed beta_alpha term
kron_two_body[ab_index] = 0.5
tensor_blocked_spin_orbitals += PolynomialTensor.apply(
np.kron, kron_tensor, self.alpha_beta
)
kron_two_body[ab_index] = 0
return cast(PolynomialTensor, tensor_blocked_spin_orbitals)
[ドキュメント] def trace_spin(self) -> PolynomialTensor:
"""Returns a :class:`~.PolynomialTensor` where the spin components have been traced out.
This will sum the :attr:`alpha` and :attr:`beta` components, tracing out the spin.
Returns:
A ``PolynomialTensor`` with the spin traced out.
"""
beta_empty = self.beta.is_empty()
beta_alpha_empty = self.beta_alpha.is_empty()
if beta_empty and beta_alpha_empty:
return cast(PolynomialTensor, 2.0 * self.alpha)
two_body = self.two_body
tensor_spin_traced = PolynomialTensor({})
tensor_spin_traced += self.alpha
tensor_spin_traced += self.beta
if beta_alpha_empty:
tensor_spin_traced += two_body.alpha
tensor_spin_traced += two_body.beta
else:
tensor_spin_traced += two_body.beta_alpha
tensor_spin_traced += two_body.alpha_beta
return tensor_spin_traced