r"""
.. _data_reuploading_classifier:
Data-reuploading classifier
===========================
*Author: Shahnawaz Ahmed (shahnawaz.ahmed95@gmail.com)*
.. meta::
:property="og:description": Implement a single-qubit universal quantum classifier using PennyLane.
:property="og:image": https://pennylane.ai/qml/_images/universal_dnn1.png
.. related::
tutorial_variational_classifier Variational quantum classifier
tutorial_multiclass_classification Multiclass margin classifier
tutorial_expressivity_fourier_series Quantum models as Fourier series
A single-qubit quantum circuit which can implement arbitrary unitary
operations can be used as a universal classifier much like a single
hidden-layered Neural Network. As surprising as it sounds,
`Pérez-Salinas et al. (2019) `_
discuss this with their idea of 'data
reuploading'. It is possible to load a single qubit with arbitrary
dimensional data and then use it as a universal classifier.
In this example, we will implement this idea with Pennylane - a
python based tool for quantum machine learning, automatic
differentiation, and optimization of hybrid quantum-classical
computations.
Background
----------
We consider a simple classification problem and will train a
single-qubit variational quantum circuit to achieve this goal. The data
is generated as a set of random points in a plane :math:`(x_1, x_2)` and
labeled as 1 (blue) or 0 (red) depending on whether they lie inside or
outside a circle. The goal is to train a quantum circuit to predict the
label (red or blue) given an input point’s coordinate.
.. figure:: ../demonstrations/data_reuploading/universal_circles.png
:scale: 65%
:alt: circles
Transforming quantum states using unitary operations
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
A single-qubit quantum state is characterized by a two-dimensional state
vector and can be visualized as a point in the so-called Bloch sphere.
Instead of just being a 0 (up) or 1 (down), it can exist in a
superposition with say 30% chance of being in the :math:`|0 \rangle` and
70% chance of being in the :math:`|1 \rangle` state. This is represented
by a state vector :math:`|\psi \rangle = 0.3|0 \rangle + 0.7|1 \rangle` -
the probability "amplitude" of the quantum state. In general we can take
a vector :math:`(\alpha, \beta)` to represent the probabilities of a qubit
being in a particular state and visualize it on the Bloch sphere as an
arrow.
.. figure:: ../demonstrations/data_reuploading/universal_bloch.png
:scale: 65%
:alt: bloch
Data loading using unitaries
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In order to load data onto a single qubit, we use a unitary operation
:math:`U(x_1, x_2, x_3)` which is just a parameterized
matrix multiplication representing the rotation of the state vector in
the Bloch sphere. E.g., to load :math:`(x_1, x_2)` into the qubit, we
just start from some initial state vector, :math:`|0 \rangle`,
apply the unitary operation :math:`U(x_1, x_2, 0)` and end up at a new
point on the Bloch sphere. Here we have padded 0 since our data is only
2D. Pérez-Salinas et al. (2019) discuss how to load a higher
dimensional data point (:math:`[x_1, x_2, x_3, x_4, x_5, x_6]`) by
breaking it down in sets of three parameters
(:math:`U(x_1, x_2, x_3), U(x_4, x_5, x_6)`).
Model parameters with data re-uploading
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Once we load the data onto the quantum circuit, we want to have some
trainable nonlinear model similar to a neural network as well as a way of
learning the weights of the model from data. This is again done with
unitaries, :math:`U(\theta_1, \theta_2, \theta_3)`, such that we load the
data first and then apply the weights to form a single layer
:math:`L(\vec \theta, \vec x) = U(\vec \theta)U(\vec x)`. In principle,
this is just application of two matrix multiplications on an input
vector initialized to some value. In order to increase the number of
trainable parameters (similar to increasing neurons in a single layer of
a neural network), we can reapply this layer again and again with new
sets of weights,
:math:`L(\vec \theta_1, \vec x) L(\vec \theta_2, , \vec x) ... L(\vec \theta_L, \vec x)`
for :math:`L` layers. The quantum circuit would look like the following:
.. figure:: ../demonstrations/data_reuploading/universal_layers.png
:scale: 75%
:alt: Layers
The cost function and "nonlinear collapse"
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
So far, we have only performed linear operations (matrix
multiplications) and we know that we need to have some nonlinear
squashing similar to activation functions in neural networks to really
make a universal classifier (Cybenko 1989). Here is where things gets a
bit quantum. After the application of the layers, we will end up at some
point on the Bloch sphere due to the sequence of unitaries implementing
rotations of the input. These are still just linear transformations of
the input state. Now, the output of the model should be a class label
which can be encoded as fixed vectors (Blue = :math:`[1, 0]`, Red =
:math:`[0, 1]`) on the Bloch sphere. We want to end up at either of them
after transforming our input state through alternate applications of
data layer and weights.
We can use the idea of the “collapse” of our quantum state into
one or other class. This happens when we measure the quantum state which
leads to its projection as either the state 0 or 1. We can compute the
fidelity (or closeness) of the output state to the class label making
the output state jump to either :math:`| 0 \rangle` or
:math:`|1\rangle`. By repeating this process several times, we can
compute the probability or overlap of our output to both labels and
assign a class based on the label our output has a higher overlap. This
is much like having a set of output neurons and selecting the one which
has the highest value as the label.
We can encode the output label as a particular quantum state that we want
to end up in and use Pennylane to find the probability of ending up in that
state after running the circuit. We construct an observable corresponding to
the output label using the `Hermitian `_
operator. The expectation value of the observable gives the overlap or fidelity.
We can then define the cost function as the sum of the fidelities for all
the data points after passing through the circuit and optimize the parameters
:math:`(\vec \theta)` to minimize the cost.
.. math::
\texttt{Cost} = \sum_{\texttt{data points}} (1 - \texttt{fidelity}(\psi_{\texttt{output}}(\vec x, \vec \theta), \psi_{\texttt{label}}))
Now, we can use our favorite optimizer to maximize the sum of the
fidelities over all data points (or batches of datapoints) and find the
optimal weights for classification. Gradient-based optimizers such as
Adam (Kingma et. al., 2014) can be used if we have a good model of
the circuit and how noise might affect it. Or, we can use some
gradient-free method such as L-BFGS (Liu, Dong C., and Nocedal, J., 1989)
to evaluate the gradient and find the optimal weights where we can
treat the quantum circuit as a black-box and the gradients are computed
numerically using a fixed number of function evaluations and iterations.
The L-BFGS method can be used with the PyTorch interface for Pennylane.
Multiple qubits, entanglement and Deep Neural Networks
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Universal Approximation Theorem declares that a neural network with
two or more hidden layers can serve as a universal function approximator.
Recently, we have witnessed remarkable progress of learning algorithms using
Deep Neural Networks.
Pérez-Salinas et al. (2019) make a connection to Deep Neural Networks by
describing that in their approach the
“layers” :math:`L_i(\vec \theta_i, \vec x )` are analogous to the size
of the intermediate hidden layer of a neural network. And the concept of
deep (multiple layers of the neural network) relates to the number
of qubits. So, multiple qubits with entanglement between them could
provide some quantum advantage over classical neural networks. But here,
we will only implement a single qubit classifier.
.. figure:: ../demonstrations/data_reuploading/universal_dnn.png
:scale: 35%
:alt: DNN
"Talk is cheap. Show me the code." - Linus Torvalds
---------------------------------------------------
"""
import pennylane as qml
from pennylane import numpy as np
from pennylane.optimize import AdamOptimizer, GradientDescentOptimizer
import matplotlib.pyplot as plt
# Set a random seed
np.random.seed(42)
# Make a dataset of points inside and outside of a circle
def circle(samples, center=[0.0, 0.0], radius=np.sqrt(2 / np.pi)):
"""
Generates a dataset of points with 1/0 labels inside a given radius.
Args:
samples (int): number of samples to generate
center (tuple): center of the circle
radius (float: radius of the circle
Returns:
Xvals (array[tuple]): coordinates of points
yvals (array[int]): classification labels
"""
Xvals, yvals = [], []
for i in range(samples):
x = 2 * (np.random.rand(2)) - 1
y = 0
if np.linalg.norm(x - center) < radius:
y = 1
Xvals.append(x)
yvals.append(y)
return np.array(Xvals), np.array(yvals)
def plot_data(x, y, fig=None, ax=None):
"""
Plot data with red/blue values for a binary classification.
Args:
x (array[tuple]): array of data points as tuples
y (array[int]): array of data points as tuples
"""
if fig == None:
fig, ax = plt.subplots(1, 1, figsize=(5, 5))
reds = y == 0
blues = y == 1
ax.scatter(x[reds, 0], x[reds, 1], c="red", s=20, edgecolor="k")
ax.scatter(x[blues, 0], x[blues, 1], c="blue", s=20, edgecolor="k")
ax.set_xlabel("$x_1$")
ax.set_ylabel("$x_2$")
Xdata, ydata = circle(500)
fig, ax = plt.subplots(1, 1, figsize=(4, 4))
plot_data(Xdata, ydata, fig=fig, ax=ax)
plt.show()
# Define output labels as quantum state vectors
def density_matrix(state):
"""Calculates the density matrix representation of a state.
Args:
state (array[complex]): array representing a quantum state vector
Returns:
dm: (array[complex]): array representing the density matrix
"""
return state * np.conj(state).T
label_0 = [[1], [0]]
label_1 = [[0], [1]]
state_labels = [label_0, label_1]
##############################################################################
# Simple classifier with data reloading and fidelity loss
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
dev = qml.device("default.qubit", wires=1)
# Install any pennylane-plugin to run on some particular backend
@qml.qnode(dev)
def qcircuit(params, x=None, y=None):
"""A variational quantum circuit representing the Universal classifier.
Args:
params (array[float]): array of parameters
x (array[float]): single input vector
y (array[float]): single output state density matrix
Returns:
float: fidelity between output state and input
"""
for p in params:
qml.Rot(*x, wires=0)
qml.Rot(*p, wires=0)
return qml.expval(qml.Hermitian(y, wires=[0]))
def cost(params, x, y, state_labels=None):
"""Cost function to be minimized.
Args:
params (array[float]): array of parameters
x (array[float]): 2-d array of input vectors
y (array[float]): 1-d array of targets
state_labels (array[float]): array of state representations for labels
Returns:
float: loss value to be minimized
"""
# Compute prediction for each input in data batch
loss = 0.0
dm_labels = [density_matrix(s) for s in state_labels]
for i in range(len(x)):
f = qcircuit(params, x=x[i], y=dm_labels[y[i]])
loss = loss + (1 - f) ** 2
return loss / len(x)
##############################################################################
# Utility functions for testing and creating batches
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
def test(params, x, y, state_labels=None):
"""
Tests on a given set of data.
Args:
params (array[float]): array of parameters
x (array[float]): 2-d array of input vectors
y (array[float]): 1-d array of targets
state_labels (array[float]): 1-d array of state representations for labels
Returns:
predicted (array([int]): predicted labels for test data
output_states (array[float]): output quantum states from the circuit
"""
fidelity_values = []
dm_labels = [density_matrix(s) for s in state_labels]
predicted = []
for i in range(len(x)):
fidel_function = lambda y: qcircuit(params, x=x[i], y=y)
fidelities = [fidel_function(dm) for dm in dm_labels]
best_fidel = np.argmax(fidelities)
predicted.append(best_fidel)
fidelity_values.append(fidelities)
return np.array(predicted), np.array(fidelity_values)
def accuracy_score(y_true, y_pred):
"""Accuracy score.
Args:
y_true (array[float]): 1-d array of targets
y_predicted (array[float]): 1-d array of predictions
state_labels (array[float]): 1-d array of state representations for labels
Returns:
score (float): the fraction of correctly classified samples
"""
score = y_true == y_pred
return score.sum() / len(y_true)
def iterate_minibatches(inputs, targets, batch_size):
"""
A generator for batches of the input data
Args:
inputs (array[float]): input data
targets (array[float]): targets
Returns:
inputs (array[float]): one batch of input data of length `batch_size`
targets (array[float]): one batch of targets of length `batch_size`
"""
for start_idx in range(0, inputs.shape[0] - batch_size + 1, batch_size):
idxs = slice(start_idx, start_idx + batch_size)
yield inputs[idxs], targets[idxs]
##############################################################################
# Train a quantum classifier on the circle dataset
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# Generate training and test data
num_training = 200
num_test = 2000
Xdata, y_train = circle(num_training)
X_train = np.hstack((Xdata, np.zeros((Xdata.shape[0], 1))))
Xtest, y_test = circle(num_test)
X_test = np.hstack((Xtest, np.zeros((Xtest.shape[0], 1))))
# Train using Adam optimizer and evaluate the classifier
num_layers = 3
learning_rate = 0.6
epochs = 10
batch_size = 32
opt = AdamOptimizer(learning_rate, beta1=0.9, beta2=0.999)
# initialize random weights
params = np.random.uniform(size=(num_layers, 3))
predicted_train, fidel_train = test(params, X_train, y_train, state_labels)
accuracy_train = accuracy_score(y_train, predicted_train)
predicted_test, fidel_test = test(params, X_test, y_test, state_labels)
accuracy_test = accuracy_score(y_test, predicted_test)
# save predictions with random weights for comparison
initial_predictions = predicted_test
loss = cost(params, X_test, y_test, state_labels)
print(
"Epoch: {:2d} | Cost: {:3f} | Train accuracy: {:3f} | Test Accuracy: {:3f}".format(
0, loss, accuracy_train, accuracy_test
)
)
for it in range(epochs):
for Xbatch, ybatch in iterate_minibatches(X_train, y_train, batch_size=batch_size):
params = opt.step(lambda v: cost(v, Xbatch, ybatch, state_labels), params)
predicted_train, fidel_train = test(params, X_train, y_train, state_labels)
accuracy_train = accuracy_score(y_train, predicted_train)
loss = cost(params, X_train, y_train, state_labels)
predicted_test, fidel_test = test(params, X_test, y_test, state_labels)
accuracy_test = accuracy_score(y_test, predicted_test)
res = [it + 1, loss, accuracy_train, accuracy_test]
print(
"Epoch: {:2d} | Loss: {:3f} | Train accuracy: {:3f} | Test accuracy: {:3f}".format(
*res
)
)
##############################################################################
# Results
# ~~~~~~~
print(
"Cost: {:3f} | Train accuracy {:3f} | Test Accuracy : {:3f}".format(
loss, accuracy_train, accuracy_test
)
)
print("Learned weights")
for i in range(num_layers):
print("Layer {}: {}".format(i, params[i]))
fig, axes = plt.subplots(1, 3, figsize=(10, 3))
plot_data(X_test, initial_predictions, fig, axes[0])
plot_data(X_test, predicted_test, fig, axes[1])
plot_data(X_test, y_test, fig, axes[2])
axes[0].set_title("Predictions with random weights")
axes[1].set_title("Predictions after training")
axes[2].set_title("True test data")
plt.show()
##############################################################################
# References
# ----------
# [1] Pérez-Salinas, Adrián, et al. “Data re-uploading for a universal
# quantum classifier.” arXiv preprint arXiv:1907.02085 (2019).
#
# [2] Kingma, Diederik P., and Ba, J. "Adam: A method for stochastic
# optimization." arXiv preprint arXiv:1412.6980 (2014).
#
# [3] Liu, Dong C., and Nocedal, J. "On the limited memory BFGS
# method for large scale optimization." Mathematical programming
# 45.1-3 (1989): 503-528.