qiskit.aqua.algorithms.QSVM¶

class
QSVM
(feature_map, training_dataset=None, test_dataset=None, datapoints=None, multiclass_extension=None, lambda2=0.001, quantum_instance=None)[código fonte]¶ Quantum SVM algorithm.
A key concept in classification methods is that of a kernel. Data cannot typically be separated by a hyperplane in its original space. A common technique used to find such a hyperplane consists on applying a nonlinear transformation function to the data. This function is called a feature map, as it transforms the raw features, or measurable properties, of the phenomenon or subject under study. Classifying in this new feature space – and, as a matter of fact, also in any other space, including the raw original one – is nothing more than seeing how close data points are to each other. This is the same as computing the inner product for each pair of data in the set. In fact we do not need to compute the nonlinear feature map for each datum, but only the inner product of each pair of data points in the new feature space. This collection of inner products is called the kernel and it is perfectly possible to have feature maps that are hard to compute but whose kernels are not.
The QSVM algorithm applies to classification problems that require a feature map for which computing the kernel is not efficient classically. This means that the required computational resources are expected to scale exponentially with the size of the problem. QSVM uses a Quantum processor to solve this problem by a direct estimation of the kernel in the feature space. The method used falls in the category of what is called supervised learning, consisting of a training phase (where the kernel is calculated and the support vectors obtained) and a test or classification phase (where new data without labels is classified according to the solution found in the training phase).
Internally, QSVM will run the binary classification or multiclass classification based on how many classes the data has. If the data has more than 2 classes then a multiclass_extension is required to be supplied. Aqua provides several
multiclass_extensions
.See also https://arxiv.org/abs/1804.11326
 Parâmetros
feature_map (
Union
[QuantumCircuit
,FeatureMap
]) – Feature map module, used to transform datatraining_dataset (
Optional
[Dict
[str
,ndarray
]]) – Training dataset.test_dataset (
Optional
[Dict
[str
,ndarray
]]) – Testing dataset.datapoints (
Optional
[ndarray
]) – Prediction dataset.multiclass_extension (
Optional
[MulticlassExtension
]) – If number of classes is greater than 2 then a multiclass scheme must be supplied, in the form of a multiclass extension.lambda2 (
float
) – L2 norm regularization factorquantum_instance (
Union
[QuantumInstance
,Backend
,BaseBackend
,None
]) – Quantum Instance or Backend
 Levanta
AquaError – Multiclass extension not supplied when number of classes > 2

__init__
(feature_map, training_dataset=None, test_dataset=None, datapoints=None, multiclass_extension=None, lambda2=0.001, quantum_instance=None)[código fonte]¶  Parâmetros
feature_map (
Union
[QuantumCircuit
,FeatureMap
]) – Feature map module, used to transform datatraining_dataset (
Optional
[Dict
[str
,ndarray
]]) – Training dataset.test_dataset (
Optional
[Dict
[str
,ndarray
]]) – Testing dataset.datapoints (
Optional
[ndarray
]) – Prediction dataset.multiclass_extension (
Optional
[MulticlassExtension
]) – If number of classes is greater than 2 then a multiclass scheme must be supplied, in the form of a multiclass extension.lambda2 (
float
) – L2 norm regularization factorquantum_instance (
Union
[QuantumInstance
,Backend
,BaseBackend
,None
]) – Quantum Instance or Backend
 Levanta
AquaError – Multiclass extension not supplied when number of classes > 2
Methods
__init__
(feature_map[, training_dataset, …]) type feature_map
Union
[QuantumCircuit
,FeatureMap
]
construct_circuit
(x1, x2[, measurement])Generate inner product of x1 and x2 with the given feature map.
construct_kernel_matrix
(x1_vec[, x2_vec, …])Construct kernel matrix, if x2_vec is None, selfinnerproduct is conducted.
get_kernel_matrix
(quantum_instance, …[, …])Construct kernel matrix, if x2_vec is None, selfinnerproduct is conducted.
load_model
(file_path)Load a model from a file path.
predict
(data[, quantum_instance])Predict using the svm.
run
([quantum_instance])Execute the algorithm with selected backend.
save_model
(file_path)Save the model to a file path.
set_backend
(backend, **kwargs)Sets backend with configuration.
setup_datapoint
(datapoints)Setup data points, if the data were there, they would be overwritten.
setup_test_data
(test_dataset)Setup test data, if the data were there, they would be overwritten.
setup_training_data
(training_dataset)Setup training data, if the data were there, they would be overwritten.
test
(data, labels[, quantum_instance])Test the svm.
train
(data, labels[, quantum_instance])Train the svm.
Attributes
BATCH_SIZE
Returns backend.
Returns quantum instance.
Return a numpy random.
returns result

property
backend
¶ Returns backend.
 Tipo de retorno
Union
[Backend
,BaseBackend
]

construct_circuit
(x1, x2, measurement=False)[código fonte]¶ Generate inner product of x1 and x2 with the given feature map.
The dimension of x1 and x2 must be the same.
 Parâmetros
x1 (numpy.ndarray) – data points, 1D array, dimension is D
x2 (numpy.ndarray) – data points, 1D array, dimension is D
measurement (bool) – add measurement gates at the end
 Retorna
constructed circuit
 Tipo de retorno

construct_kernel_matrix
(x1_vec, x2_vec=None, quantum_instance=None)[código fonte]¶ Construct kernel matrix, if x2_vec is None, selfinnerproduct is conducted.
Notas
When using statevector_simulator, we only build the circuits for Psi(x1)0> rather than Psi(x2)^dagger Psi(x1)0>, and then we perform the inner product classically. That is, for statevector_simulator, the total number of circuits will be O(N) rather than O(N^2) for qasm_simulator.
 Parâmetros
x1_vec (numpy.ndarray) – data points, 2D array, N1xD, where N1 is the number of data, D is the feature dimension
x2_vec (numpy.ndarray) – data points, 2D array, N2xD, where N2 is the number of data, D is the feature dimension
quantum_instance (QuantumInstance) – quantum backend with all settings
 Retorna
2D matrix, N1xN2
 Tipo de retorno
numpy.ndarray
 Levanta
AquaError – Quantum instance is not present.

static
get_kernel_matrix
(quantum_instance, feature_map, x1_vec, x2_vec=None, enforce_psd=True)[código fonte]¶ Construct kernel matrix, if x2_vec is None, selfinnerproduct is conducted.
Notas
When using statevector_simulator, we only build the circuits for Psi(x1)0> rather than Psi(x2)^dagger Psi(x1)0>, and then we perform the inner product classically. That is, for statevector_simulator, the total number of circuits will be O(N) rather than O(N^2) for qasm_simulator.
 Parâmetros
quantum_instance (QuantumInstance) – quantum backend with all settings
feature_map (FeatureMap) – a feature map that maps data to feature space
x1_vec (numpy.ndarray) – data points, 2D array, N1xD, where N1 is the number of data, D is the feature dimension
x2_vec (numpy.ndarray) – data points, 2D array, N2xD, where N2 is the number of data, D is the feature dimension
enforce_psd (bool) – enforces that the kernel matrix is positive semidefinite by setting negative eigenvalues to zero. This is only applied in the symmetric case, i.e., if x2_vec == None.
 Retorna
2D matrix, N1xN2
 Tipo de retorno
numpy.ndarray

load_model
(file_path)[código fonte]¶ Load a model from a file path.
 Parâmetros
file_path (str) – the path of the saved model.

predict
(data, quantum_instance=None)[código fonte]¶ Predict using the svm.
 Parâmetros
data (numpy.ndarray) – NxD array, where N is the number of data, D is the feature dimension.
quantum_instance (QuantumInstance) – quantum backend with all setting
 Retorna
predicted labels, Nx1 array
 Tipo de retorno
numpy.ndarray
 Levanta
AquaError – Quantum instance is not present.

property
quantum_instance
¶ Returns quantum instance.
 Tipo de retorno
Optional
[QuantumInstance
]

property
random
¶ Return a numpy random.

property
ret
¶ returns result

run
(quantum_instance=None, **kwargs)¶ Execute the algorithm with selected backend.
 Parâmetros
quantum_instance (
Union
[QuantumInstance
,Backend
,BaseBackend
,None
]) – the experimental setting.kwargs (dict) – kwargs
 Retorna
results of an algorithm.
 Tipo de retorno
dict
 Levanta
AquaError – If a quantum instance or backend has not been provided

save_model
(file_path)[código fonte]¶ Save the model to a file path.
 Parâmetros
file_path (str) – a path to save the model.

set_backend
(backend, **kwargs)¶ Sets backend with configuration.
 Tipo de retorno
None

setup_datapoint
(datapoints)[código fonte]¶ Setup data points, if the data were there, they would be overwritten.
 Parâmetros
datapoints (numpy.ndarray) – prediction dataset.

setup_test_data
(test_dataset)[código fonte]¶ Setup test data, if the data were there, they would be overwritten.
 Parâmetros
test_dataset (dict) – test dataset.

setup_training_data
(training_dataset)[código fonte]¶ Setup training data, if the data were there, they would be overwritten.
 Parâmetros
training_dataset (dict) – training dataset.

test
(data, labels, quantum_instance=None)[código fonte]¶ Test the svm.
 Parâmetros
data (numpy.ndarray) – NxD array, where N is the number of data, D is the feature dimension.
labels (numpy.ndarray) – Nx1 array, where N is the number of data
quantum_instance (QuantumInstance) – quantum backend with all setting
 Retorna
accuracy
 Tipo de retorno
float
 Levanta
AquaError – Quantum instance is not present.

train
(data, labels, quantum_instance=None)[código fonte]¶ Train the svm.
 Parâmetros
data (numpy.ndarray) – NxD array, where N is the number of data, D is the feature dimension.
labels (numpy.ndarray) – Nx1 array, where N is the number of data
quantum_instance (QuantumInstance) – quantum backend with all setting
 Levanta
AquaError – Quantum instance is not present.