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LCU + Block encoding demo #888

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60 changes: 60 additions & 0 deletions demonstrations/tutorial_lcu_blockencoding.metadata.json
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{
"title": "Linear combination of unitaries and block encodings",
"authors": [
{
"id": "juan_miguel_arrazola"
},
{
"id": "diego_guala"
},
{
"id": "jay_soni"
}
],
"dateOfPublication": "2023-08-31T00:00:00+00:00",
"dateOfLastModification": "2023-08-31T00:00:00+00:00",
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"categories": [
"Algorithms",
"Quantum Computing"
],
"tags": [],
"previewImages": [
{
"type": "thumbnail",
"uri": "/_images/thumbnail_lcu_blockencoding.png"
},
{
"type": "large_thumbnail",
"uri": "/_static/large_demo_thumbnails/thumbnail_large_lcu_blockencoding.png"
}
],
"seoDescription": "Master the basics of LCUs and their applications",
"doi": "",
"canonicalURL": "/qml/demos/tutorial_lcu_blockencoding",
"references": [
{
"id": "qsvt",
"type": "article",
"title": "Quantum singular value transformation and beyond: exponential improvements for quantum matrix arithmetics",
"authors": "András Gilyén, Yuan Su, Guang Hao Low, Nathan Wiebe",
"year": "2019",
"publisher": "",
"journal": "",
"url": "https://dl.acm.org/doi/abs/10.1145/3313276.3316366"
}
],
"basedOnPapers": [],
"referencedByPapers": [],
"relatedContent": [
{
"type": "demonstration",
"id": "tutorial_intro_qsvt",
"weight": 1.0
},
{
"type": "demonstration",
"id": "tutorial_apply_qsvt",
"weight": 1.0
}
]
}
288 changes: 288 additions & 0 deletions demonstrations/tutorial_lcu_blockencoding.py
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r"""Linear combination of unitaries and block encodings
=============================================================

.. meta::
:property="og:description": Master the basics of LCUs and their applications
:property="og:image": https://pennylane.ai/qml/_images/thumbnail_lcu_blockencoding.png

.. related::

tutorial_intro_qsvt Intro to QSVT

*Author: Juan Miguel Arrazola, Diego Guala, and Jay Soni — Posted: August, 2023.*
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If I (Juan Miguel) had to summarize quantum computing in one sentence, it would be this: information is
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encoded in quantum states and processed using `unitary operations <https://en.wikipedia.org/wiki/Unitary_operator>`_.
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The challenge of quantum algorithms is to design and build these unitaries to perform interesting and
useful tasks. My colleague `Nathan Wiebe <https://scholar.google.ca/citations?user=DSgKHOQAAAAJ&hl=en>`_
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once told me that some of his early research was motivated by a simple
question: Quantum computers can implement products of unitaries --- after all
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that's how we build circuits from a `universal gate set <https://en.wikipedia.org/wiki/Quantum_logic_gate#Universal_quantum_gates>`_.
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What about **sums of unitaries**? 🤔
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In this tutorial you will learn the basics of one of the most versatile tools in quantum algorithms:
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linear combinations of unitaries; or LCUs for short. You will also understand how to
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use LCUs to create another powerful building block of quantum algorithms: block encodings.
Among their many uses, they allow us to transform quantum states by non-unitary operators.
Block encodings are useful in a variety of contexts, perhaps most famously in
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`qubitization <https://arxiv.org/abs/1610.06546>`_ and the `quantum
singular value transformation (QSVT) <https://pennylane.ai/qml/demos/tutorial_intro_qsvt>`_.

|

.. figure:: ../demonstrations/lcu_blockencoding/thumbnail_lcu_blockencoding.png
:align: center
:width: 50%
:target: javascript:void(0)

|

LCUs
----
Linear combinations of unitaries are straightforward --- it’s already explained in the name: we
decompose operators as a weighted sum of unitaries. Mathematically, this means expresssing
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an operator :math:`A` in terms of coefficients :math:`\alpha_{k}` and unitaries :math:`U_{k}` as

.. math:: A = \sum_{k=0}^{N-1} \alpha_k U_k.

A general way to build LCUs is to employ properties of the **Pauli basis**.
This is the set of all products of Pauli matrices :math:`{I, X, Y, Z}`. It forms a complete basis
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for the space of operators acting on :math:`n` qubits. Thus any operator can be expressed in the Pauli basis,
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which immediately gives an LCU decomposition. PennyLane allows you to decompose any matrix in the Pauli basis using the
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:func:`~.pennylane.pauli_decompose` function. The coefficients :math:`\alpha_k` and the unitaries
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:math:`U_k` from the decomposition can be accessed directly from the result. We show how to do this
in the code below for a simple example.

"""
import numpy as np
import pennylane as qml

a = 0.25
b = 0.75

# matrix to be decomposed
A = np.array(
[[a, 0, 0, b],
[0, -a, b, 0],
[0, b, a, 0],
[b, 0, 0, -a]]
)

LCU = qml.pauli_decompose(A)

print(f"LCU decomposition:\n {LCU}")
print(f"Coefficients:\n {LCU.coeffs}")
print(f"Unitaries:\n {LCU.ops}")


##############################################################################
# PennyLane uses a smart Pauli decomposition based on vectorizing the matrix and exploiting properties of
# the `Walsh-Hadamard transform <https://en.wikipedia.org/wiki/Hadamard_transform>`_,
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# but the cost still scales as ~ :math:`O(n 4^n)` for :math:`n` qubits. Be careful.
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#
# It's good to remember that many types of Hamiltonians are already compactly expressed
# in the Pauli basis, for example in various `Ising models <https://en.wikipedia.org/wiki/Ising_model>`_
# and molecular Hamiltonians using the `Jordan-Wigner transformation <https://en.wikipedia.org/wiki/Jordan%E2%80%93Wigner_transformation>`_.
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# This is very useful since we get an LCU decomposition for free.
#
# Block Encodings
# ---------------
# Going from an LCU to a quantum circuit that applies the associated operator is also straightforward
# once you know the trick: to prepare, select, and unprepare.
#
# Starting from the LCU decomposition :math:`A = \sum_{k=0}^{N-1} \alpha_k U_k` with positive, real coefficients, we define the prepare
# (PREP) operator:
#
# .. math:: \text{PREP}|0\rangle = \sum_k \sqrt{\frac{|\alpha|_k}{\lambda}}|k\rangle,
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#
# and the select (SEL) operator:
#
# .. math:: \text{SEL}|k\rangle |\psi\rangle = |k\rangle U_k |\psi\rangle.
#
# They are aptly named: PREP prepares a state whose amplitudes
# are determined by the coefficients of the LCU, and SEL selects which unitary is applied.
#
# .. note::
#
# Some important details about the equations above:
#
# * :math:`\lambda` is a normalization constant, defined as :math:`\lambda = \sum_k |\alpha_k|`.
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# * :math:`SEL` acts this way on any state :math:`|\psi\rangle`
# * We are using :math:`|0\rangle` as shorthand to denote the all-zero state for multiple qubits.
#
# The final trick is to combine PREP and SEL to make :math:`A` appear 🪄:
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#
# .. math:: \langle 0| \text{PREP}^\dagger \cdot \text{SEL} \cdot \text{PREP} |0\rangle|\psi\rangle = A/\lambda |\psi\rangle.
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#
# If you're up for it, it's illuminating to go through the math and show how :math:`A` comes out on the right
# side of the equation.
# (Tip: calculate the action of :math:`\text{PREP}^\dagger` on :math:`\langle 0|`, not on the output
# state after :math:`\text{SEL} \cdot \text{PREP}`).
#
# Otherwise, the intuitive way to understand this equation is that we apply PREP, SEL, and then invert PREP. If
# we measure :math:`|0\rangle` in the auxiliary qubits, the input state :math:`|\psi\rangle` will be transformed by
# :math:`A` (up to normalization). The figure below shows this as a circuit with four unitaries in SEL.
#
# |
#
# .. figure:: ../demonstrations/lcu_blockencoding/schematic.png
# :align: center
# :width: 50%
# :target: javascript:void(0)
#
# |
#
# The circuit
#
# .. math:: U = \text{PREP}^\dagger \cdot \text{SEL} \cdot \text{PREP},
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#
# is a **block encoding** of :math:`A`, up to normalization. The reason for this name is that if we write :math:`U`
# as a matrix, the operator :math:`A` is encoded inside a block of :math:`U` as
#
# .. math:: U = \begin{bmatrix} A & \cdot \\ \cdot & \cdot \end{bmatrix}.
#
# This block is defined by the subspace of all states where the auxiliary qubits are in state
# :math:`|0\rangle`.
#
#
# PennyLane supports direct implementation of `prepare <https://docs.pennylane.ai/en/stable/code/api/pennylane.StatePrep.html>`_
# and `select <https://docs.pennylane.ai/en/stable/code/api/pennylane.Select.html>`_
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# operators. We'll go through them individually and use them to construct a block encoding circuit.
# Prepare circuits can be constructed using the :class:`~.pennylane.StatePrep` operation, which takes
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# the normalized target state as input:

dev1 = qml.device("default.qubit", wires=1)

# normalized square roots of coefficients
alphas = (np.sqrt(LCU.coeffs) / np.linalg.norm(np.sqrt(LCU.coeffs)))


@qml.qnode(dev1)
def prep_circuit():
qml.StatePrep(alphas, wires=0)
return qml.state()


print("Target state: ", alphas)
print("Output state: ", np.real(prep_circuit()))

##############################################################################
# Similarly, select circuits can be implemented using :class:`~.pennylane.Select`, which takes the
# target unitaries as input. We specify the control wires directly, but the system wires are inherited
# from the unitaries. Since :func:`~.pennylane.pauli_decompose` uses a canonical wire ordering, we
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# first map the wires to those used for the system register in our circuit:

dev2 = qml.device("default.qubit", wires=3)
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# unitaries
ops = LCU.ops
# relabeling wires 0 --> 1, and 1 --> 2
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unitaries = [qml.map_wires(op, {0: 1, 1: 2}) for op in ops]


@qml.qnode(dev2)
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def sel_circuit(qubit_value):
qml.BasisState(qubit_value, wires=0)
qml.Select(unitaries, control=0)
return qml.expval(qml.PauliZ(2))

print(qml.draw(sel_circuit)([0]))
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##############################################################################
# Based on the controlled operations, the circuit above will flip the measured qubit
# if the input is :math:`|1\rangle` and leave it unchanged if the
# input is :math:`|0\rangle`. The output expecation values correspond to these states:
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print('Expectation value for input |0>:', sel_circuit([0]))
print('Expectation value for input |1>:', sel_circuit([1]))

##############################################################################
# We can now combine these to construct a full LCU circuit. Here we make use of the
# :func:`~.pennylane.adjoint` function as a convenient way to invert the prepare circuit. We have
# chosen an input matrix that is already normalized, so it can be seen appearing directly in the
# top-left block of the unitary describing the full circuit --- the mark of a successful block
# encoding.


@qml.qnode(dev2)
def lcu_circuit(): # block_encode
# PREP
qml.StatePrep(alphas, wires=0)

# SEL
qml.Select(unitaries, control=0)

# PREP_dagger
qml.adjoint(qml.StatePrep(alphas, wires=0))
return qml.state()


output_matrix = qml.matrix(lcu_circuit)()
print("A:\n", A, "\n")
print("Block-encoded A:\n")
print(np.real(np.round(output_matrix,2)))

##############################################################################
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# Application: Projectors
# -----------------------
# Suppose we wanted to project our quantum state :math:`|\psi\rangle` onto the state
# :math:`|\phi\rangle`. We could accomplish this by applying the projector
# :math:`| \phi \rangle\langle \phi |` to :math:`|\psi\rangle`. However, we cannot directly apply
# projectors as gates in our quantum circuits because they are **not** unitary operations.
# We can instead use a simple LCU decomposition which holds for any projector:
#
# .. math::
# | \phi \rangle\langle \phi | = \frac{1}{2} \cdot (\mathbb{I}) + \frac{1}{2} \cdot (2 \cdot | \phi \rangle\langle \phi | - \mathbb{I})
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#
# Both terms in the expression above are unitary (try proving it for yourself). We can now use this
# LCU decomposition to block-encode the projector! As an example, let's block-encode the projector
# :math:`| 0 \rangle\langle 0 |` that projects a state to the :math:`|0\rangle` state:
#
# .. math:: | 0 \rangle\langle 0 | = \begin{bmatrix}
# 1 & 0 \\
# 0 & 0 \\
# \end{bmatrix}.
#

coeffs = np.array([1/2, 1/2])
alphas = np.sqrt(coeffs) / np.linalg.norm(np.sqrt(coeffs))

proj_unitaries = [qml.Identity(0), qml.PauliZ(0)]

##############################################################################
# Note that the second term in our LCU simplifies to a Pauli :math:`Z` operation. We can now
# construct a full LCU circuit and verify that :math:`| 0 \rangle\langle 0 |` is block-encoded in
# the top left block of the matrix.

def lcu_circuit(): # block_encode
# PREP
qml.StatePrep(alphas, wires="ancilla")

# SEL
qml.Select(proj_unitaries, control="ancilla")

# PREP_dagger
qml.adjoint(qml.StatePrep(alphas, wires="ancilla"))
return qml.state()


output_matrix = qml.matrix(lcu_circuit)()
print("Block-encoded projector:\n")
print(np.real(np.round(output_matrix,2)))


##############################################################################
# Final thoughts
# -------------------
# LCUs and block encodings are often associated with advanced algorithms that require the full power
# of fault-tolerant quantum computers. The truth is that they are basic constructions with
# broad applicability that can be useful for all kinds of hardware and simulators. If you're working
# on quantum algorithms and applications in any capacity, these are techniques that you should
# master. PennyLane is equipped with the tools to help you get there.
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##############################################################################
# About the authors
# -----------------
# .. include:: ../_static/authors/juan_miguel_arrazola.txt
# .. include:: ../_static/authors/jay_soni.txt
# .. include:: ../_static/authors/diego_guala.txt
7 changes: 7 additions & 0 deletions demos_quantum-computing.rst
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Expand Up @@ -173,6 +173,12 @@ such as benchmarking and characterizing quantum processors.
:figure: demonstrations/apply_qsvt/thumbnail_tutorial_QSVT_for_Matrix_Inversion.png
:description: :doc:`demos/tutorial_apply_qsvt`
:tags: quantumcomputing qsvt optimization

.. gallery-item::
:tooltip: Linear combinations of unitaries and block encodings
:figure: demonstrations/lcu_blockencoding/thumbnail_lcu_blockencoding.png
:description: :doc:`demos/tutorial_lcu_blockencoding`
:tags: quantumcomputing LCU algorithms qsvt

:html:`</div></div><div style='clear:both'>`

Expand Down Expand Up @@ -205,5 +211,6 @@ such as benchmarking and characterizing quantum processors.
demos/tutorial_intro_qsvt
demos/tutorial_grovers_algorithm
demos/tutorial_apply_qsvt
demos/tutorial_lcu_blockencoding