Quantum Computing /

A self-contained, reader-friendly introduction to the principles and applications of quantum computing. Especially valuable to those without a prior knowledge of quantum mechanics, this electrical engineering text presents the concepts and workings of quantum information processing systems in a clea...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Lala, Parag k., 1948- (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York, N.Y. : McGraw-Hill Education, [2019].
Edición:1st edition.
Temas:
Quantum computing.
Quantum theory.
TECHNOLOGY & ENGINEERING / Electrical.
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover
  • Title Page
  • Copyright Page
  • Contents
  • Dedication
  • Preface
  • 1 Complex Numbers, Vector Space, and Dirac Notation
  • 1.1 Complex Numbers
  • 1.2 Complex Conjugation
  • 1.3 Vector Space
  • 1.4 Basis Set
  • 1.5 Dirac Notation
  • 1.6 Inner Product
  • 1.7 Linearly Dependent and Independent Vectors
  • 1.8 Dual Vector Space
  • 1.9 Computational Basis
  • 1.10 Outer Product
  • References
  • 2 Basics of Quantum Mechanics
  • 2.1 Limitations of Classical Physics
  • 2.2 Photoelectric Effect
  • 2.3 Classical Electromagnetic Theory
  • 2.4 Rutherford?s Model of the Atom
  • 2.5 Bohr?s Model of Atoms
  • 2.6 Particle and Wave Nature of Light
  • 2.7 Wave Function
  • 2.8 Postulates of Quantum Mechanics
  • References
  • 3 Matrices and Operators
  • 3.1 Matrices
  • 3.2 Square Matrices
  • 3.3 Diagonal (or Triangular) Matrix
  • 3.4 Operators
  • 3.5 Linear Operator
  • 3.6 Commutator
  • 3.7 Matrix Representation of a Linear Operator
  • 3.8 Symmetric Matrix
  • 3.9 Transpose Operation
  • 3.10 Orthogonal Matrices
  • 3.11 Identity Operator
  • 3.12 Adjoint Operator
  • 3.13 Hermitian Operator
  • 3.14 Unitary Operators
  • 3.15 Projection Operator
  • References
  • 4 Boolean Algebra, Logic Gates, and Quantum Information Processing
  • 4.1 Boolean Algebra
  • 4.2 Classical Circuit Computation Model
  • 4.3 Universal Logic Gates
  • 4.4 Quantum Computation
  • 4.5 The Quantum Bit and Its Representations
  • 4.6 Superposition in Quantum Systems
  • 4.7 Quantum Register
  • References
  • 5 Quantum Gates and Circuits
  • 5.1 X Gate
  • 5.2 Y Gate
  • 5.3 Z Gate
  • 5.4 NOT (Square Root of NOT) Gate
  • 5.5 Hadamard Gate
  • 5.6 Phase Gate
  • 5.7 T Gate
  • 5.8 Reversible Logic
  • 5.9 CNOT Gate
  • 5.10 Controlled-U Gate
  • 5.11 Reversible Gates
  • References
  • 6 Tensor Products, Superposition, and Quantum Entanglement
  • 6.1 Tensor Products
  • 6.2 Multi-Qubit Systems
  • 6.3 Superposition
  • 6.4 Entanglement
  • 6.5 Decoherence
  • References
  • 7 Teleportation and Superdense Coding
  • 7.1 Quantum Teleportation
  • 7.2 No-Cloning Theorem
  • 7.3 Superdense Coding
  • References
  • 8 Quantum Error Correction
  • 8.1 Classical Error-Correcting Codes
  • 8.2 Quantum Error-Correcting Codes
  • 8.3 Shor?s 3-Qubit Bit-Flop Code
  • 8.4 Error Correction
  • 8.5 Shor?s 9 Qubit Code
  • References
  • 9 Quantum Algorithms
  • 9.1 Deutsch?s Algorithm
  • 9.2 Deutsch?Jozsa Algorithm
  • 9.3 Grover?s Search Algorithm
  • 9.4 Shor?s Factoring Algorithm
  • References
  • 10 Quantum Cryptography
  • 10.1 Principles of Information Security
  • 10.2 One-Time Pad
  • 10.3 Public Key Cryptography
  • 10.4 RSA Coding Scheme
  • 10.5 Quantum Cryptography
  • 10.6 Quantum Key Distribution
  • 10.7 BB84
  • 10.8 Ekart 91
  • References
  • Index
  • A
  • B
  • C
  • D
  • E
  • F
  • G
  • H
  • I
  • J
  • K
  • L
  • M
  • N
  • O
  • P
  • Q
  • R
  • S
  • T
  • U
  • V
  • W
  • X
  • Y
  • Z.

Ejemplares similares