Buch, Englisch, 391 Seiten, Format (B × H): 178 mm x 254 mm, Gewicht: 894 g
Buch, Englisch, 391 Seiten, Format (B × H): 178 mm x 254 mm, Gewicht: 894 g
Reihe: Advances in Applied Mathematics
ISBN: 978-1-032-20648-6
Verlag: Taylor & Francis Ltd (Sales)
Quantum Computation presents the mathematics of quantum computation. The purpose is to introduce the topic of quantum computing to students in computer science, physics and mathematics who have no prior knowledge of this field.
The book is written in two parts. The primary mathematical topics required for an initial understanding of quantum computation are dealt with in Part I: sets, functions, complex numbers and other relevant mathematical structures from linear and abstract algebra. Topics are illustrated with examples focussing on the quantum computational aspects which will follow in more detail in Part II.
Part II discusses quantum information, quantum measurement and quantum algorithms. These topics provide foundations upon which more advanced topics may be approached with confidence.
Features
- A more accessible approach than most competitor texts, which move into advanced, research-level topics too quickly for today's students.
- Part I is comprehensive in providing all necessary mathematical underpinning, particularly for those who need more opportunity to develop their mathematical competence.
- More confident students may move directly to Part II and dip back into Part I as a reference.
- Ideal for use as an introductory text for courses in quantum computing.
- Fully worked examples illustrate the application of mathematical techniques.
- Exercises throughout develop concepts and enhance understanding.
- End-of-chapter exercises offer more practice in developing a secure foundation.
Zielgruppe
Postgraduate, Professional, and Undergraduate Advanced
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Part I Mathematical Foundations for Quantum Computation. 1. Mathematical preliminaries. 2. Functions and their application to digital gates. 3. Complex numbers. 4. Vectors. 5. Matrices. 6. Vector spaces. 7. Eigenvalues and eigenvectors of a matrix. 8. Group theory. 9. Linear transformations. 10. Tensor product spaces. 11. Linear operators and their matrix representations. Part II Foundations of quantum-gate computation. 12. Introduction to Part II. 13. Axioms for quantum computation. 14. Quantum measurement 1. 15. Quantum information processing 1: the quantum emulation of familiar invertible digital gates. 16. Unitary extensions of the gates notQ, FQ, TQ and PQ: more general quantum inputs. 17. Quantum information processing 2: the quantum emulation of arbitrary Boolean functions. 18. Invertible digital circuits and their quantum emulations. 19. Quantum measurement 2: general pure states, Bell states. 20. Quantum information processing 3. 21. More on quantum gates and circuits: those without digital equivalents. 22. Quantum algorithms 1. 23. Quantum algorithms 2: Simon's algorithm.
