Foundations of quantum programming /
Foundations of Quantum Programming discusses how new programming methodologies and technologies developed for current computers can be extended to exploit the unique power of quantum computers, which promise dramatic advantages in processing speed over currently available computer systems. Governmen...
Clasificación: | Libro Electrónico |
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Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Cambridge, MA :
Morgan Kaufmann, an imprint of Elsevier,
[2016]
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Temas: | |
Acceso en línea: | Texto completo (Requiere registro previo con correo institucional) |
Tabla de Contenidos:
- Front Cover; Foundations of Quantum Programming; Copyright; Contents; Preface; Acknowledgments; Part I: Introduction and preliminaries; Chapter 1: Introduction; 1.1 Brief history of quantum programming research; 1.1.1 Design of Quantum Programming Languages; 1.1.2 Semantics of Quantum Programming Languages; 1.1.3 Verification and Analysis of Quantum Programs; 1.2 Approaches to quantum programming; 1.2.1 Superposition-of-Data
- Quantum Programs with Classical Control; 1.2.2 Superposition-of-Programs
- Quantum Programs with Quantum Control; 1.3 Structure of the Book; Chapter 2: Preliminaries
- 2.1 Quantum mechanics2.1.1 Hilbert Spaces; 2.1.2 Linear Operators; 2.1.3 Unitary Transformations; 2.1.4 Quantum Measurements; 2.1.5 Tensor Products of Hilbert Spaces; 2.1.6 Density Operators; 2.1.7 Quantum Operations; 2.2 Quantum circuits; 2.2.1 Basic Definitions; 2.2.2 One-Qubit Gates; 2.2.3 Controlled Gates; 2.2.4 Quantum Multiplexor; 2.2.5 Universality of Gates; 2.2.6 Measurement in Circuits; 2.3 Quantum algorithms; 2.3.1 Quantum Parallelism and Interference; 2.3.2 Deutsch-Jozsa Algorithm; 2.3.3 Grover Search Algorithm; 2.3.4 Quantum Walks; 2.3.5 Quantum-Walk Search Algorithm
- 2.3.6 Quantum Fourier Transform2.3.7 Phase Estimation; 2.4 Bibliographic remarks; Part II: Quantum programswith classicalcontrol; Chapter 3: Syntax and semantics of quantum programs; 3.1 Syntax; 3.2 Operational semantics; 3.3 Denotational semantics; 3.3.1 Basic Properties of Semantic Functions; 3.3.2 Quantum Domains; 3.3.3 Semantic Function of Loop; 3.3.4 Change and Access of Quantum Variables; 3.3.5 Termination and Divergence Probabilities; 3.3.6 Semantic Functions as Quantum Operations; 3.4 Classical recursion in quantum programming; 3.4.1 Syntax; 3.4.2 Operational Semantics
- 3.4.3 Denotational Semantics3.4.4 Fixed Point Characterization; 3.5 Illustrative example: Grover quantum search; 3.6 Proofs of lemmas; 3.7 Bibliographic remarks; Chapter 4: Logic for quantum programs; 4.1 Quantum predicates; 4.1.1 Quantum Weakest Preconditions; 4.2 Floyd-Hoare logic for quantum programs; 4.2.1 Correctness Formulas; 4.2.2 Weakest Preconditions of Quantum Programs; 4.2.3 Proof System for Partial Correctness; 4.2.4 Proof System for Total Correctness; 4.2.5 An Illustrative Example: Reasoning aboutthe Grover Algorithm; 4.3 Commutativity of quantum weakest preconditions
- 4.4 Bibliographic remarksChapter 5: Analysis of quantum programs; 5.1 Termination analysis of quantum while-loops; 5.1.1 Quantum while-Loops with Unitary Bodies; 5.1.2 General Quantum while-Loops; 5.1.3 An Example; 5.2 Quantum graph theory; 5.2.1 Basic Definitions; 5.2.2 Bottom Strongly Connected Components; 5.2.3 Decomposition of the State Hilbert Space; 5.3 Reachability analysis of quantum Markov chains; 5.3.1 Reachability Probability; 5.3.2 Repeated Reachability Probability; 5.3.3 Persistence Probability; 5.4 Proofs of technical lemmas; 5.5 Bibliographic remarks