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qiskit.aqua.algorithms.QAOA

class QAOA(operator=None, optimizer=None, p=1, initial_state=None, mixer=None, initial_point=None, gradient=None, expectation=None, include_custom=False, max_evals_grouped=1, aux_operators=None, callback=None, quantum_instance=None)[ソース]

The Quantum Approximate Optimization Algorithm.

QAOA is a well-known algorithm for finding approximate solutions to combinatorial-optimization problems. The QAOA implementation in Aqua directly extends VQE and inherits VQE’s general hybrid optimization structure. However, unlike VQE, which can be configured with arbitrary variational forms, QAOA uses its own fine-tuned variational form, which comprises \(p\) parameterized global \(x\) rotations and \(p\) different parameterizations of the problem hamiltonian. QAOA is thus principally configured by the single integer parameter, p, which dictates the depth of the variational form, and thus affects the approximation quality.

An optional array of \(2p\) parameter values, as the initial_point, may be provided as the starting beta and gamma parameters (as identically named in the original QAOA paper) for the QAOA variational form.

An operator may optionally also be provided as a custom mixer Hamiltonian. This allows, as discussed in this paper for quantum annealing, and in this paper for QAOA, to run constrained optimization problems where the mixer constrains the evolution to a feasible subspace of the full Hilbert space.

An initial state from Aqua’s initial_states may optionally be supplied.

パラメータ
  • operator (Union[OperatorBase, LegacyBaseOperator, None]) – Qubit operator

  • optimizer (Optional[Optimizer]) – A classical optimizer.

  • p (int) – the integer parameter p as specified in https://arxiv.org/abs/1411.4028, Has a minimum valid value of 1.

  • initial_state (Optional[InitialState]) – An optional initial state to prepend the QAOA circuit with

  • mixer (Union[OperatorBase, LegacyBaseOperator, None]) – the mixer Hamiltonian to evolve with. Allows support of optimizations in constrained subspaces as per https://arxiv.org/abs/1709.03489

  • initial_point (Optional[ndarray]) – An optional initial point (i.e. initial parameter values) for the optimizer. If None then it will simply compute a random one.

  • gradient (Union[GradientBase, Callable[[Union[ndarray, List]], List], None]) – An optional gradient operator respectively a gradient function used for optimization.

  • expectation (Optional[ExpectationBase]) – The Expectation converter for taking the average value of the Observable over the var_form state function. When None (the default) an ExpectationFactory is used to select an appropriate expectation based on the operator and backend. When using Aer qasm_simulator backend, with paulis, it is however much faster to leverage custom Aer function for the computation but, although VQE performs much faster with it, the outcome is ideal, with no shot noise, like using a state vector simulator. If you are just looking for the quickest performance when choosing Aer qasm_simulator and the lack of shot noise is not an issue then set include_custom parameter here to True (defaults to False).

  • include_custom (bool) – When expectation parameter here is None setting this to True will allow the factory to include the custom Aer pauli expectation.

  • max_evals_grouped (int) – Max number of evaluations performed simultaneously. Signals the given optimizer that more than one set of parameters can be supplied so that potentially the expectation values can be computed in parallel. Typically this is possible when a finite difference gradient is used by the optimizer such that multiple points to compute the gradient can be passed and if computed in parallel improve overall execution time. Ignored if a gradient operator or function is given.

  • aux_operators (Optional[List[Union[OperatorBase, LegacyBaseOperator, None]]]) – Optional list of auxiliary operators to be evaluated with the eigenstate of the minimum eigenvalue main result and their expectation values returned. For instance in chemistry these can be dipole operators, total particle count operators so we can get values for these at the ground state.

  • callback (Optional[Callable[[int, ndarray, float, float], None]]) – a callback that can access the intermediate data during the optimization. Four parameter values are passed to the callback as follows during each evaluation by the optimizer for its current set of parameters as it works towards the minimum. These are: the evaluation count, the optimizer parameters for the variational form, the evaluated mean and the evaluated standard deviation.

  • quantum_instance (Union[QuantumInstance, Backend, BaseBackend, None]) – Quantum Instance or Backend

__init__(operator=None, optimizer=None, p=1, initial_state=None, mixer=None, initial_point=None, gradient=None, expectation=None, include_custom=False, max_evals_grouped=1, aux_operators=None, callback=None, quantum_instance=None)[ソース]
パラメータ
  • operator (Union[OperatorBase, LegacyBaseOperator, None]) – Qubit operator

  • optimizer (Optional[Optimizer]) – A classical optimizer.

  • p (int) – the integer parameter p as specified in https://arxiv.org/abs/1411.4028, Has a minimum valid value of 1.

  • initial_state (Optional[InitialState]) – An optional initial state to prepend the QAOA circuit with

  • mixer (Union[OperatorBase, LegacyBaseOperator, None]) – the mixer Hamiltonian to evolve with. Allows support of optimizations in constrained subspaces as per https://arxiv.org/abs/1709.03489

  • initial_point (Optional[ndarray]) – An optional initial point (i.e. initial parameter values) for the optimizer. If None then it will simply compute a random one.

  • gradient (Union[GradientBase, Callable[[Union[ndarray, List]], List], None]) – An optional gradient operator respectively a gradient function used for optimization.

  • expectation (Optional[ExpectationBase]) – The Expectation converter for taking the average value of the Observable over the var_form state function. When None (the default) an ExpectationFactory is used to select an appropriate expectation based on the operator and backend. When using Aer qasm_simulator backend, with paulis, it is however much faster to leverage custom Aer function for the computation but, although VQE performs much faster with it, the outcome is ideal, with no shot noise, like using a state vector simulator. If you are just looking for the quickest performance when choosing Aer qasm_simulator and the lack of shot noise is not an issue then set include_custom parameter here to True (defaults to False).

  • include_custom (bool) – When expectation parameter here is None setting this to True will allow the factory to include the custom Aer pauli expectation.

  • max_evals_grouped (int) – Max number of evaluations performed simultaneously. Signals the given optimizer that more than one set of parameters can be supplied so that potentially the expectation values can be computed in parallel. Typically this is possible when a finite difference gradient is used by the optimizer such that multiple points to compute the gradient can be passed and if computed in parallel improve overall execution time. Ignored if a gradient operator or function is given.

  • aux_operators (Optional[List[Union[OperatorBase, LegacyBaseOperator, None]]]) – Optional list of auxiliary operators to be evaluated with the eigenstate of the minimum eigenvalue main result and their expectation values returned. For instance in chemistry these can be dipole operators, total particle count operators so we can get values for these at the ground state.

  • callback (Optional[Callable[[int, ndarray, float, float], None]]) – a callback that can access the intermediate data during the optimization. Four parameter values are passed to the callback as follows during each evaluation by the optimizer for its current set of parameters as it works towards the minimum. These are: the evaluation count, the optimizer parameters for the variational form, the evaluated mean and the evaluated standard deviation.

  • quantum_instance (Union[QuantumInstance, Backend, BaseBackend, None]) – Quantum Instance or Backend

Methods

__init__([operator, optimizer, p, …])

type operator

Union[OperatorBase, LegacyBaseOperator, None]

cleanup_parameterized_circuits()

set parameterized circuits to None

compute_minimum_eigenvalue([operator, …])

Computes minimum eigenvalue.

construct_circuit(parameter)

Return the circuits used to compute the expectation value.

construct_expectation(parameter)

Generate the ansatz circuit and expectation value measurement, and return their runnable composition.

find_minimum([initial_point, var_form, …])

Optimize to find the minimum cost value.

get_optimal_circuit()

Get the circuit with the optimal parameters.

get_optimal_cost()

Get the minimal cost or energy found by the VQE.

get_optimal_vector()

Get the simulation outcome of the optimal circuit.

get_prob_vector_for_params(…[, …])

Helper function to get probability vectors for a set of params

get_probabilities_for_counts(counts)

get probabilities for counts

print_settings()

Preparing the setting of VQE into a string.

run([quantum_instance])

Execute the algorithm with selected backend.

set_backend(backend, **kwargs)

Sets backend with configuration.

supports_aux_operators()

Whether computing the expectation value of auxiliary operators is supported.

Attributes

aux_operators

Returns aux operators

backend

Returns backend.

expectation

The expectation value algorithm used to construct the expectation measurement from the observable.

initial_point

Returns initial point

operator

Returns operator

optimal_params

The optimal parameters for the variational form.

optimizer

Returns optimizer

quantum_instance

Returns quantum instance.

random

Return a numpy random.

setting

Prepare the setting of VQE as a string.

var_form

Returns variational form

property aux_operators

Returns aux operators

戻り値の型

Optional[List[Optional[OperatorBase]]]

property backend

Returns backend.

戻り値の型

Union[Backend, BaseBackend]

cleanup_parameterized_circuits()

set parameterized circuits to None

compute_minimum_eigenvalue(operator=None, aux_operators=None)

Computes minimum eigenvalue. Operator and aux_operators can be supplied here and if not None will override any already set into algorithm so it can be reused with different operators. While an operator is required by algorithms, aux_operators are optional. To 『remove』 a previous aux_operators array use an empty list here.

パラメータ
  • operator (Union[OperatorBase, LegacyBaseOperator, None]) – If not None replaces operator in algorithm

  • aux_operators (Optional[List[Union[OperatorBase, LegacyBaseOperator, None]]]) – If not None replaces aux_operators in algorithm

戻り値の型

MinimumEigensolverResult

戻り値

MinimumEigensolverResult

construct_circuit(parameter)

Return the circuits used to compute the expectation value.

パラメータ

parameter (Union[List[float], List[Parameter], ndarray]) – Parameters for the ansatz circuit.

戻り値の型

List[QuantumCircuit]

戻り値

A list of the circuits used to compute the expectation value.

construct_expectation(parameter)

Generate the ansatz circuit and expectation value measurement, and return their runnable composition.

パラメータ

parameter (Union[List[float], List[Parameter], ndarray]) – Parameters for the ansatz circuit.

戻り値の型

OperatorBase

戻り値

The Operator equalling the measurement of the ansatz StateFn by the Observable’s expectation StateFn.

例外

AquaError – If no operator has been provided.

property expectation

The expectation value algorithm used to construct the expectation measurement from the observable.

戻り値の型

ExpectationBase

find_minimum(initial_point=None, var_form=None, cost_fn=None, optimizer=None, gradient_fn=None)

Optimize to find the minimum cost value.

パラメータ
  • initial_point (Optional[ndarray]) – If not None will be used instead of any initial point supplied via constructor. If None and None was supplied to constructor then a random point will be used if the optimizer requires an initial point.

  • var_form (Union[QuantumCircuit, VariationalForm, None]) – If not None will be used instead of any variational form supplied via constructor.

  • cost_fn (Optional[Callable]) – If not None will be used instead of any cost_fn supplied via constructor.

  • optimizer (Optional[Optimizer]) – If not None will be used instead of any optimizer supplied via constructor.

  • gradient_fn (Optional[Callable]) – Optional gradient function for optimizer

戻り値

Optimized variational parameters, and corresponding minimum cost value.

戻り値の型

dict

例外

ValueError – invalid input

get_optimal_circuit()

Get the circuit with the optimal parameters.

戻り値の型

QuantumCircuit

get_optimal_cost()

Get the minimal cost or energy found by the VQE.

戻り値の型

float

get_optimal_vector()

Get the simulation outcome of the optimal circuit.

戻り値の型

Union[List[float], Dict[str, int]]

get_prob_vector_for_params(construct_circuit_fn, params_s, quantum_instance, construct_circuit_args=None)

Helper function to get probability vectors for a set of params

get_probabilities_for_counts(counts)

get probabilities for counts

property initial_point

Returns initial point

戻り値の型

Optional[ndarray]

property operator

Returns operator

戻り値の型

Optional[OperatorBase]

property optimal_params

The optimal parameters for the variational form.

戻り値の型

List[float]

property optimizer

Returns optimizer

戻り値の型

Optional[Optimizer]

print_settings()

Preparing the setting of VQE into a string.

戻り値

the formatted setting of VQE

戻り値の型

str

property quantum_instance

Returns quantum instance.

戻り値の型

Optional[QuantumInstance]

property random

Return a numpy random.

run(quantum_instance=None, **kwargs)

Execute the algorithm with selected backend.

パラメータ
  • quantum_instance (Union[QuantumInstance, Backend, BaseBackend, None]) – the experimental setting.

  • kwargs (dict) – kwargs

戻り値

results of an algorithm.

戻り値の型

dict

例外

AquaError – If a quantum instance or backend has not been provided

set_backend(backend, **kwargs)

Sets backend with configuration.

戻り値の型

None

property setting

Prepare the setting of VQE as a string.

classmethod supports_aux_operators()

Whether computing the expectation value of auxiliary operators is supported.

If the minimum eigensolver computes an eigenstate of the main operator then it can compute the expectation value of the aux_operators for that state. Otherwise they will be ignored.

戻り値の型

bool

戻り値

True if aux_operator expectations can be evaluated, False otherwise

property var_form

Returns variational form

戻り値の型

Union[QuantumCircuit, VariationalForm, None]