量子计算与量子信息:英文版

量子计算与量子信息:英文版
作 者: Michael Nielsen Isaac Chuang
出版社: 高等教育出版社
丛编项: 教育部高等教育司推荐国外优秀信息科学与技术系列教学用书
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作者简介

  Michael nielsen is a Postdoctoral research fellow at the university of Queensland.he was born in Brisbane,Austalia,and received his education at the University of Queensland,obtaining postgraducate degrees in mathematics and physics before receiving his Ph.D.in Physics as a Fulbright Scholar at the University of new mexico.he has held a Vistiong position at the los Alamos national Laboratory,and was the Tolman postdoctoral Fellow at the California Institute of technology.

内容简介

This book provides an introduction to the main ideas and techniques of the field of quantum computation and quantum information. The rapid rate of progress in this field and its cross-disciplinary nature have made it difficult for newcomers to obtain a broad overview of the most important techniques and results of the field. Our purpose in this book is therefore twofold. First, we introduce the background material in computer science, mathematics and physics necessary to understand quantum computation and quantum information. This is done at a level comprehensible to readers with a background at least the equal of a beginning graduate student in one or more of these three disciplines; the most important requirements are a certain level of mathematical maturity, and the desire to learn about quantum computation and quantum information. The second purpose of the book is to develop in detail the central results of quantum computation and quantum information. With thorough study the reader should develop a wo...

图书目录

Preface

Acknowledgements

Nomenclature and notation

Part I Fundamental concepts

Introduction and overview

1.1 Global perspectives

1.1.1 History of quantum computation and quantum information

1.1.2 Future directions

1.2 Quantum bits

1.2.1 Multiple qubits

1.3 Quantum computation

1.3.1 Single qubit gates

1.3.2 Multiple qubit gates

1.3.3 Measurements in bases other than the computational basis

1.3.4 Quantum circuits

1.3.5 Qubit copying circuit

1.3.6 Example: Bell states

1.3.7 Example: quantum teleportation

1.4 Quantum algorithms

1.4.1 Classical computations on a quantum computer

1.4.2 Quantum parallelism

1.4.3 Deutsch''s algorithm

1.4.4 The Deutsch-Jozsa algorithm

1.4.5 Quantum algorithms summarized

1.5 Experimental quantum information processing

1.5.1 The Stern-Gerlach experiment

1.5.2 Prospects for practical quantum information processing

1.6 Quantum information

1.6.1 Quantum information theory: example problems

1.6.2 Quantum information in a wider context

2 Introduction to quantum mechanics

2.1 Linear algebra

2.1.1 Bases and linear independence

2.1.2 Linear operators and matrices

2.1.3 The Pauli matrices

2.1.4 Inner products

2.1.5 Eigenvectors and eigenvalues

2.1.6 Adjoints and Hermitian operators

2.1.7 Tensor products

2.1.8 Operator functions

2.1.9 The commutator and anti-commutator

2.1.10 The polar and singular value decompositions

2.2 The postulates of quantum mechanics

2.2.1 State space

2.2.2 Evolution

2.2.3 Quantum measurement

2.2.4 Distinguishing quantum states

2.2.5 Projective measurements

2.2.6 POVM measurements

2.2.7 Phase

2.2.8 Composite systems

2.2.9 Quantum mechanics: a global view

2.3 Application: superdense coding

2.4 The density operator

2.4.1 Ensembles of quantum states

2.4.2 General properties of the density operator

2.4.3 The reduced density operator

2.5 The Schmidt decomposition and purifications

2.6 EPR and the Bell inequality

3 Introduction to computer science

3.1 Models for computation

3.1.1 Turing machines

3.1.2 Circuits

3.2 The analysis of computational problems

3.2.1 How to quantify computational resources

3.2.2 Computational complexity

3.2.3 Decision problems and the complexity classes P and NP

3.2.4 A plethora of complexity classes

3.2.5 Energy and computation

3.3 Perspectives on computer science

Part II Quantum computation

4 Quantum circuits

4.1 Quantum algorithms

4.2 Single qubit operations

4.3 Controlled operations

4.4 Measurement

4.5 Universal quantum gates

4.5.1 Two-level unitary gates are universal

4.5.2 Single qubit and CNOT gates are universal

4.5.3 A discrete set of universal operations

4.5.4 Approximating arbitrary unitary gates is generically hard

4.5.5 Quantum computational complexity

4.6 Summary of the quantum circuit model of computation

4.7 Simulation of quantum systems

4.7.1 Simulation in action

4.7.2 The quantum simulation algorithm

4.7.3 An illustrative example

4.7.4 Perspectives on quantum simulation

5 The quantum Fourier transform and its applications

5.1 The quantum Fourier transform

5.2 Phase estimation

5.2.1 Performance and requirements

5.3 Applications: order-finding and factoring

5.3.1 Application: order-finding

5.3.2 Application: factoring

5.4 General applications of the quantum Fourier transform

5.4.1 Period-finding

5.4.2 Discrete logarithms

5.4.3 The hidden subgroup problem

5.4.4 Other quantum algorithms

Quantum search algorithms

6.1 The quantum search algorithm

6.1.1 The oracle

6.1.2 The procedure

6.1.3 Geometric visualization

6.1.4 Performance

6.2 Quantum search as a quantum simulation

6.3 Quantum counting

6.4 Speeding up the solution of NP--complete problems

6.5 Quantum search of an unstructured database

6.6 Optimality of the search algorithm

6.7 Black box algorithm limits

7 Quantum computers: physical realization

7.1 Guiding principles

7.2 Conditions for quantum computation

7.2.1 Representation of quantum information

7.2.2 Performance of unitary transformations

7.2.3 Preparation of fiducial initial states

7.2.4 Measurement of output result

7.3 Harmonic oscillator quantum computer

7.3.1 Physical apparatus

7.3.2 The Hamiltonian

7.3.3 Quantum computation

7.3.4 Drawbacks

7.4 Optical photon quantum computer

7.4.1 Physical apparatus

7.4.2 Quantum computation

7.4.3 Drawbacks

7.5 Optical cavity quantum electrodynamics

7.5.1 Physical apparatus

7.5.2 The Hamiltonian

7.5.3 Single-photon single-atom absorption and refraction

7.5.4 Quantum computation

7.6 Ion traps

7.6.1 Physical apparatus

7.6.2 The Hamiltonian

7.6.3 Quantum computation

7.6.4 Experiment

7.7 Nuclear magnetic resonance

7.7.1 Physical apparatus

7.7.2 The Hamiltonian

7.7.3 Quantum computation

7.7.4 Experiment

7.8 Other implementation schemes

Part III Quantum information

8 Quantum noise and quantum operations

8.1 Classical noise and Markov processes

8.2 Quantum operations

8.2.1 Overview

8.2.2 Environments and quantum operations

8.2.3 Operator-sum representation

8.2.4 Axiomatic approach to quantum operations

8.3 Examples of quantum noise and quantum operations

8.3.1 Trace and partial trace

8.3.2 Geometric picture of single qubit quantum operations

8.3.3 Bit flip and phase flip channels

8.3.4 Depolarizing channel

8.3.5 Amplitude damping

8.3.6 Phase damping

8.4 Applications of quantum operations

8.4.1 Master equations

8.4.2 Quantum process tomography

8.5 Limitations of the quantum operations formalism

9 Distance measures for quantum information

9.1 Distance measures for classical information

9.2 How close are two quantum states

9.2.1 Trace distance

9.2.2 Fidelity

9.2.3 Relationships between distance measures

9.3 How well does a quantum channel preserve information

10 Quantum error-correction

10.1 Introduction

10.1.1 .The three qubit bit,flip code

10.1.2 Three qubit phase flip code

10.2 The Shor code

10.3 Theory of quantum error-correction

10.3.1 Discretization of, the errors

10.3.2 Independent error models

10.3.3 Degenerate codes

10.3.4 The quantum Hamming bound

10.4 Constructing quantum codes

10.4.1 Classical linear codes

10.4.2 Calderbank-Shor-Steane codes

10.5 Stabilizer codes

10.5.1 The stabilizer formalism

10.5.2 Unitary gates and the stabilizer formalism

10.5.3 Measurement in the stabilizer formalism

10.5.4 The Gottesman-Knill theorem

10.5.5 Stabilizer code constructions

10.5.6 Examples

10.5.7 Standard form for a stabilizer code

10.5.8 Quantum circuits for encoding, decoding, and correction

10.6 Fault-tolerant quantum computation

10.6.1 Fault-tolerance: the big picture

10.6.2 Fault-tolerant quantum logic

10.6.3 Fault-tolerant measurement

10.6.4 Elements of resilient quantum computation

11 Entropy and information

11.1 Shannon entropy

11.2 Basic properties of entropy

11.2.1 The binary entropy

11.2.2 The relative entropy

11.2.3 Conditional entropy and mutual information

11.2.4 The data processing inequality

11.3 Von Neumann entropy

11.3.1 Quantum relative entropy

11.3.2 Basic properties of entropy

11.3.3 Measurements and entropy

11.3.4 Subadditivity

11.3.5 Concavity of the entropy

11.3.6 The entropy of a mixture of quantum states

11.4 Strong subadditivity

11.4.1 Proof of strong subadditivity

11.4.2 Strong subadditivity: elementary applications

12 Quantum information theory

12.1 Distinguishing quantum states and the accessible information

12.1.1 The Holevo bound

12.1.2 Example applications of the Holevo bound

12.2 Data compression

12.2.1 Shannon''s noiseless channel coding theorem

12.2.2 Schumacher''s quantum noiseless channel coding theorem

12.3 Classical information over noisy quantum channels

12.3.1 Communication over noisy classical channels

12.3.2 Communication over noisy quantum channels

12.4 Quantum information over noisy quantum channels

12.4.1 Entropy exchange and the quantum Fano inequality

12.4.2 The quantum data processing inequality

12.4.3 Quantum Singleton bound

12.4.4 Quantum error-correction, refrigeration and Maxwell''s demon

12.5 Entanglement as a physical resource

12.5.i Transforming bi-partite pure state entanglement

12.5.2 Entanglement distillation and dilution

12.5.3 Entanglement distillation and quantum error-correction

12.6 Quantum cryptography

12.6.1 Private key cryptography

12.6.2 Privacy amplification and information reconciliation

12.6.3 Quantum key distribution

12.6.4 Privacy and coherent information

12.6.5 The security of quantum key distribution

Appendices

Appendix 1: Notes on basic probability theory

Appendix 2: Group theory

A2.1 Basic definitions

A2.1.1 Generators

A2.1.2 Cyclic groups

A2.1.3 Cosets

A2.2 Representations

A2.2.1 Equivalence and reducibility

A2.2.2 0rthogonality

A2.2.3 The regular representation

A2.3 Fourier transforms

Appendix 3: The Solovay-Kitaev theorem

Appendix 4: Number theory

A4.1 Fundamentals

A4.2 Modular arithmetic and Euclid''s algorithm

A4.3 Reduction of factoring to order-finding

A4.4 Continued fractions

Appendix 5: Public key cryptography and the RSA cryp~

Appendix 6: Proof of Lieb''s theorem

Bibliography

Index