Quantum Computing: From Linear Algebra to Physical Realizations Contributor(s): Nakahara, Mikio (Author) |
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ISBN: 0750309830 ISBN-13: 9780750309837 Publisher: CRC Press OUR PRICE: $228.00 Product Type: Hardcover Published: January 2008 Annotation: Quantum computing is a relatively young field found at the intersection between information science and quantum physics. It describes the manipulation of information stored in the quantum states of a physical system, which has properties that sharply contrast with those of conventional classical information. The potential for exploitation of these properties-quantum information processing-is huge. Quantum algorithms running on the holy grail of QI research, a quantum computer, could be faster than any foreseeable classical computer. Quantum Computing: From Linear Algebra to Physical Realizations is a complete introduction to the subject, based on courses given by the authors in both Japan and Europe. The text divides into two parts: the first, an introductory overview of quantum information theory, including a discussion of the famous Grover and Shor algorithms and the introduction of the concept of a qubit (quantum-bit). The second part, which makes this title unique, is a comprehensive discussion of the experimental approaches currently being developed to make quantum computing a reality. These range from optical techniques- already successfully used for quantum cryptography-through solid state/superconducting and BEC methods to ion traps-the most likely candidate for eventual success. |
Additional Information |
BISAC Categories: - Computers | Mathematical & Statistical Software - Mathematics | Algebra - Linear - Computers | Enterprise Applications - General |
Dewey: 621.391 |
LCCN: 2007044310 |
Physical Information: 1.08" H x 6.24" W x 9.69" (1.66 lbs) 438 pages |
Descriptions, Reviews, Etc. |
Publisher Description: Covering both theory and progressive experiments, Quantum Computing: From Linear Algebra to Physical Realizations explains how and why superposition and entanglement provide the enormous computational power in quantum computing. This self-contained, classroom-tested book is divided into two sections, with the first devoted to the theoretical aspects of quantum computing and the second focused on several candidates of a working quantum computer, evaluating them according to the DiVincenzo criteria. Topics in Part I
Topics in Part II
Looking at the ways in which quantum computing can become reality, this book delves into enough theoretical background and experimental research to support a thorough understanding of this promising field. |