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  • Book Overview & Buying Dancing with Qubits
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Dancing with Qubits

Dancing with Qubits

By : Robert S. Sutor
5 (24)
Buy this Book
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Dancing with Qubits

Dancing with Qubits

5 (24)
By: Robert S. Sutor
Buy this Book

Overview of this book

Dancing with Qubits, Second Edition, is a comprehensive quantum computing textbook that starts with an overview of why quantum computing is so different from classical computing and describes several industry use cases where it can have a major impact. A full description of classical computing and the mathematical underpinnings of quantum computing follows, helping you better understand concepts such as superposition, entanglement, and interference. Next up are circuits and algorithms, both basic and sophisticated, as well as a survey of the physics and engineering ideas behind how quantum computing hardware is built. Finally, the book looks to the future and gives you guidance on understanding how further developments may affect you. This new edition is updated throughout with more than 100 new exercises and includes new chapters on NISQ algorithms and quantum machine learning. Understanding quantum computing requires a lot of math, and this book doesn't shy away from the necessary math concepts you'll need. Each topic is explained thoroughly and with helpful examples, leaving you with a solid foundation of knowledge in quantum computing that will help you pursue and leverage quantum-led technologies.
Table of Contents (26 chapters)
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Preface
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Preface
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For whom did I write this book?
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What does this book cover?
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What conventions do I use in this book?
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Get in touch
1
I Foundations
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I Foundations
Free Chapter
2
Why Quantum Computing
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Why Quantum Computing
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Topics covered in this chapter
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1.1 The mysterious quantum bit
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1.2 I’m awake!
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1.3 Why quantum computing is different
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1.4 Applications to artificial intelligence
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1.5 Applications to financial services
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1.6 What about cryptography?
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1.7 Summary
3
They’re Not Old, They’re Classics
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They’re Not Old, They’re Classics
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Topics covered in this chapter
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2.1 What’s inside a computer?
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2.2 The power of two
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2.3 True or false?
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2.4 Logic circuits
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2.5 Addition, logically
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2.6 Algorithmically speaking
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2.7 Growth, exponential and otherwise
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2.8 How hard can that be?
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2.9 Summary
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More Numbers Than You Can Imagine
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More Numbers Than You Can Imagine
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Topics covered in this chapter
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3.1 Natural numbers
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3.2 Whole numbers
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3.3 Integers
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3.4 Rational numbers
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3.5 Real numbers
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3.6 Structure
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3.7 Modular arithmetic
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3.8 Doubling down
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3.9 Complex numbers, algebraically
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3.10 Summary
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Planes and Circles and Spheres, Oh My
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Planes and Circles and Spheres, Oh My
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Topics covered in this chapter
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4.1 Functions
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4.2 The real plane
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4.3 Trigonometry
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4.4 From Cartesian to polar coordinates
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4.5 The complex “plane”
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4.6 Real three dimensions
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4.7 Summary
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Dimensions
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Dimensions
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Topics covered in this chapter
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5.1 R2 and C1
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5.2 Vector spaces
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5.3 Linear maps
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5.4 Matrices
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5.5 Matrix algebra
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5.6 The determinant and trace
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5.7 Length and preserving it
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5.8 Unitary transformations
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5.9 Change of basis
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5.10 Eigenvectors and eigenvalues
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5.11 Direct sums
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5.12 Homomorphisms
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5.13 Systems of linear equations
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5.14 Summary
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6 What Do You Mean “Probably”?
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6 What Do You Mean “Probably”?
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Topics covered in this chapter
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6.1 Being discrete
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6.2 More formally
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6.3 Wrong again?
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6.4 Probability and error detection
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6.5 Randomness
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6.6 Expectation
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6.7 Hellinger distance
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6.8 Markov and Chebyshev go to the casino
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6.9 Summary
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II Quantum Computing
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II Quantum Computing
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One Qubit
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One Qubit
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Topics covered in this chapter
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7.1 Introducing quantum bits
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7.2 Bras and kets
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7.3 The complex math and physics of a single qubit
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7.4 A nonlinear projection
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7.5 The Bloch sphere
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7.6 Professor Hadamard, meet Professor Pauli
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7.7 Gates and unitary matrices
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7.8 Summary
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Two Qubits, Three
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Two Qubits, Three
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Topics covered in this chapter
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8.1 Tensor products
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8.2 Entanglement
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8.3 Multi-qubit gates
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8.4 The cat
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8.5 Summary
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Wiring Up the Circuits
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Wiring Up the Circuits
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Topics covered in this chapter
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9.1 So many gates
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9.2 From gates to circuits
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9.3 Building blocks and universality
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9.4 Arithmetic
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9.5 Welcome to Delphi
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9.6 Amplitude amplification and interference
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9.7 Searching with Grover
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9.8 The Deutsch-Jozsa algorithm
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9.9 The Bernstein-Vazirani algorithm
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9.10 Simon’s algorithm
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9.11 Summary
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From Circuits to Algorithms
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From Circuits to Algorithms
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Topics covered in this chapter
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10.1 Quantum Fourier Transform
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10.2 Factoring
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10.3 How hard can that be, again?
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10.4 Phase kickback
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10.5 Eigenvalue and phase estimation
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10.6 Order and period finding
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10.7 Shor’s factoring algorithm
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10.8 Summary
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Getting Physical
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Getting Physical
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Topics covered in this chapter
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11.1 That’s not logical
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11.2 What does it take to be a qubit?
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11.3 Quantum cores and interconnects
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11.4 Decoherence
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11.5 Error correction for physical qubits
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11.6 Quantum benchmarks
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11.7 The software stack and access
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11.8 Simulation
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11.9 Light and photons
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11.10 Summary
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III Advanced Topics
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III Advanced Topics
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Considering NISQ Algorithms
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Considering NISQ Algorithms
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Topics covered in this chapter
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12.1 Cost functions and optimization
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12.2 Heuristics
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12.3 Hermitian matrices again
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12.4 Expectation and the variational principle
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12.5 Time evolution
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12.6 Parameterized circuits
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12.7 The Hamiltonian
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12.8 Quantum approximate optimization algorithm (QAOA)
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12.9 Is NISQ worth it?
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12.10 Summary
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Introduction to Quantum Machine Learning
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Introduction to Quantum Machine Learning
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Topics covered in this chapter
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13.1 What is machine learning?
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13.2 Methods for encoding data
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13.3 Quantum neural networks
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13.4 Quantum kernels for SVMs
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13.5 Other quantum machine learning research areas
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13.6 Summary
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Questions about the Future
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Questions about the Future
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Topics covered in this chapter
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14.1 Ecosystem and community
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14.2 Applications and strategy
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14.3 Computing system access
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14.4 Software
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14.5 Hardware
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14.6 Education
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14.7 Workforce
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14.8 Summary
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Afterword
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Afterword
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A Quick Reference
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Topics covered in this chapter
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A.1 One qubit kets
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A.2 Two qubit kets
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A.3 Pauli gates and matrices
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A.4 Pauli strings of length 2
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A.5 Greek letters
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B Notices
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B Notices
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Topics covered in this chapter
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B.1 Photos, images, and diagrams
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B.2 Marks
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B.3 Creative Commons Attribution-NoDerivs 2.0 Generic
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B.4 Creative Commons Attribution-ShareAlike 2.0 Germany
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B.5 Creative Commons Attribution 3.0 Unported
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B.6 Creative Commons Attribution-ShareAlike 3.0 Unported
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B.7 Los Alamos National Laboratory
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B.8 Python 3 license
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C Production Notes
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Topics covered in this chapter
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C.1 How this book was built
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C.2 Citing this book
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C.3 Python version
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C.4 LaTeX environment
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Other Books You May Enjoy
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Other Books You May Enjoy
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References
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References
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Index
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Index
Appendices
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Appendices

1.7 Summary

In this first chapter, we examined what motivates the recent interest in quantum computers. The lone 1s and 0s of classical computing bits are extended and complemented by the infinite states of qubits, also known as quantum bits. The properties of superposition and entanglement give us access to many dimensions of working memory that are unavailable to classical computers.

Industry use cases for quantum computing are nascent, but the areas where experts believe it will be applicable sooner are chemistry, materials science, and financial services. AI is another area where quantum may boost performance for some calculations.

There has been confusion in traditional and social media about the interplay of security, information encryption, and quantum computing. The major areas of misunderstanding are the necessary performance requirements and the timeline.

In the next chapter, we look at classical bit-based computing to more precisely and technically explore how quantum computing may help us attack problems that are otherwise impossible today. In Chapter 3, “More Numbers Than You Can Imagine,” through Chapter 6, “What Do You Mean “Probably”?,” we work through the mathematics necessary for you to see how quantum computing works. There is a lot to cover, but it is worth it to be able to go deeper than a merely superficial understanding of the “whats,” “hows,” and “whys” of quantum computing.

End of Chapter 2
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