Cover Image
Read Now

A Practical Guide to Quantum Machine Learning and Quantum Optimization Hands-On Approach to Modern Quantum Algorithms

This book also shows you how to train quantum machine learning models, such as quantum support vector machines, quantum neural networks, and quantum generative adversarial networks. The book takes a straightforward path to help you learn about quantum algorithms, illustrating them with code that...

Full description

Bibliographic Details
Main Authors: Combarro, Elias F., González-Castillo, Samuel (Author)
Other Authors: Di Meglio, Alberto (writer of foreword)
Format: eBook
Language:English
Published: Birmingham Packt Publishing, Limited 2023
Edition:1st edition
Subjects:
Quantum Computing / Fast
Optimisation Mathématique
Mathematical Optimization / Http://id.loc.gov/authorities/subjects/sh85082127
Machine Learning / Http://id.loc.gov/authorities/subjects/sh85079324
Mathematical Optimization / Fast
Informatique Quantique
Quantum Computing / Http://id.loc.gov/authorities/subjects/sh2014002839
Machine Learning / Fast
Apprentissage Automatique
Online Access:
Collection: O'Reilly - Collection details see MPG.ReNa
LEADER 07235nmm a2200457 u 4500
001 EB002159851
003 EBX01000000000000001297966
005 00000000000000.0
007 cr|||||||||||||||||||||
008 230516 ||| eng
020 |a 9781804618301 
050 4 |a QA76.889 
100 1 |a Combarro, Elias F. 
245 0 0 |a A Practical Guide to Quantum Machine Learning and Quantum Optimization  |h [electronic resource]  |b Hands-On Approach to Modern Quantum Algorithms  |c Elías F. Combarro, Samuel González-Castillo ; foreword by Alberto Di Meglio 
250 |a 1st edition 
260 |a Birmingham  |b Packt Publishing, Limited  |c 2023 
300 |a 680 p. 
505 0 |a Running constrained problems on quantum annealers -- Solving optimization problems on quantum annealers with Leap -- The Leap annealers -- Embeddings and annealer topologies -- Controlling annealing parameters -- The importance of coupling strengths -- Classical and hybrid samplers -- Classical solvers -- Hybrid solvers -- Summary -- Chapter 5: QAOA: Quantum Approximate Optimization Algorithm -- From adiabatic computing to QAOA -- Discretizing adiabatic quantum computing -- QAOA: The algorithm -- Circuits for QAOA -- Estimating the energy -- QUBO and HOBO -- Using QAOA with Qiskit 
505 0 |a Cover -- Title Page -- Copyright and Credits -- Foreword -- Acknowledgements -- Table of Contents -- Preface -- Part 1: I, for One, Welcome our New Quantum Overlords -- Chapter 1: Foundations of Quantum Computing -- Quantum computing: the big picture -- The basics of the quantum circuit model -- Working with one qubit and the Bloch sphere -- What is a qubit? -- Dirac notation and inner products -- One-qubit quantum gates -- The Bloch sphere and rotations -- Hello, quantum world! -- Working with two qubits and entanglement -- Two-qubit states -- Two-qubit gates: tensor products 
505 0 |a The CNOT gate -- Entanglement -- The no-cloning theorem -- Controlled gates -- Hello, entangled world! -- Working with multiple qubits and universality -- Multi-qubit systems -- Multi-qubit gates -- Universal gates in quantum computing -- Summary -- Chapter 2: The Tools of the Trade in Quantum Computing -- Tools for quantum computing: a non-exhaustive overview -- A non-exhaustive survey of frameworks and platforms -- Qiskit, PennyLane, and Ocean -- Working with Qiskit -- An overview of the Qiskit framework -- Using Qiskit Terra to build quantum circuits -- Initializing circuits -- Quantum gates 
505 0 |a Measurements -- Using Qiskit Aer to simulate quantum circuits -- Let's get real: using IBM Quantum -- Working with PennyLane -- Circuit engineering 101 -- PennyLane's interoperability -- Love is in the Aer -- Connecting to IBMQ -- Summary -- Part 2: When Time is Gold: Tools for Quantum Optimization -- Chapter 3: Working with Quadratic Unconstrained Binary Optimization Problems -- The Max-Cut problem and the Ising model -- Graphs and cuts -- Formulating the problem -- The Ising model -- Enter quantum: formulating optimization problems the quantum way -- From classical variables to qubits 
505 0 |a Computing expectation values with Qiskit -- Moving from Ising to QUBO and back -- Combinatorial optimization problems with the QUBO model -- Binary linear programming -- The Knapsack problem -- Graph coloring -- The Traveling Salesperson Problem -- Other problems and other formulations -- Summary -- Chapter 4: Adiabatic Quantum Computing and Quantum Annealing -- Adiabatic quantum computing -- Quantum annealing -- Using Ocean to formulate and transform optimization problems -- Constrained quadratic models in Ocean -- Solving constrained quadratic models with dimod 
653 |a Quantum computing / fast 
653 |a Optimisation mathématique 
653 |a Mathematical optimization / http://id.loc.gov/authorities/subjects/sh85082127 
653 |a Machine learning / http://id.loc.gov/authorities/subjects/sh85079324 
653 |a Mathematical optimization / fast 
653 |a Informatique quantique 
653 |a Quantum computing / http://id.loc.gov/authorities/subjects/sh2014002839 
653 |a Machine learning / fast 
653 |a Apprentissage automatique 
700 1 |a González-Castillo, Samuel  |e author 
700 1 |a Di Meglio, Alberto  |e writer of foreword 
041 0 7 |a eng  |2 ISO 639-2 
989 |b OREILLY  |a O'Reilly 
500 |a Description based upon print version of record. - Using QAOA with Hamiltonians 
856 4 0 |u https://learning.oreilly.com/library/view/~/9781804613832/?ar  |x Verlag  |3 Volltext 
082 0 |a 006.3/843 
520 |a This book also shows you how to train quantum machine learning models, such as quantum support vector machines, quantum neural networks, and quantum generative adversarial networks. The book takes a straightforward path to help you learn about quantum algorithms, illustrating them with code that's ready to be run on quantum simulators and actual quantum computers. You'll also learn how to utilize programming frameworks such as IBM's Qiskit, Xanadu's PennyLane, and D-Wave's Leap. Through reading this book, you will not only build a solid foundation of the fundamentals of quantum computing, but you will also become familiar with a wide variety of modern quantum algorithms. Moreover, this book will give you the programming skills that will enable you to start applying quantum methods to solve practical problems right away.  
520 |a Work with fully explained algorithms and ready-to-use examples that can be run on quantum simulators and actual quantum computers with this comprehensive guide Key Features Get a solid grasp of the principles behind quantum algorithms and optimization with minimal mathematical prerequisites Learn the process of implementing the algorithms on simulators and actual quantum computers Solve real-world problems using practical examples of methods Book Description This book provides deep coverage of modern quantum algorithms that can be used to solve real-world problems. You'll be introduced to quantum computing using a hands-on approach with minimal prerequisites. You'll discover many algorithms, tools, and methods to model optimization problems with the QUBO and Ising formalisms, and you will find out how to solve optimization problems with quantum annealing, QAOA, Grover Adaptive Search (GAS), and VQE.  
520 |a What you will learn Review the basics of quantum computing Gain a solid understanding of modern quantum algorithms Understand how to formulate optimization problems with QUBO Solve optimization problems with quantum annealing, QAOA, GAS, and VQE Find out how to create quantum machine learning models Explore how quantum support vector machines and quantum neural networks work using Qiskit and PennyLane Discover how to implement hybrid architectures using Qiskit and PennyLane and its PyTorch interface Who this book is for This book is for professionals from a wide variety of backgrounds, including computer scientists and programmers, engineers, physicists, chemists, and mathematicians. Basic knowledge of linear algebra and some programming skills (for instance, in Python) are assumed, although all mathematical prerequisites will be covered in the appendices 

Similar Items