Product Description

In the 1990's it was realized that quantum physics has some spectacular applications in computer science. This book is a concise introduction to quantum computation, developing the basic elements of this new branch of computational theory without assuming any background in physics. It begins with an introduction to the quantum theory from a computer-science perspective. It illustrates the quantum-computational approach with several elementary examples of quantum speed-up, before moving to the major applications: Shor's factoring algorithm, Grover's search algorithm, and quantum error correction. The book is intended primarily for computer scientists who know nothing about quantum theory, but will also be of interest to physicists who want to learn the theory of quantum computation, and philosophers of science interested in quantum foundational issues. It evolved during six years of teaching the subject to undergraduates and graduate students in computer science, mathematics, engineering, and physics, at Cornell University.

Product Details

• Amazon Sales Rank: #39718 in Books
• Published on: 2007-09-17
• Number of items: 1
• Binding: Hardcover
• 236 pages

Review
"...what it treats, it treats extremely well, with rigor and attention to detail that reveals a deep understanding of the subject... "I truly hope that Mermin's book will nurture the next generations of scientists in their understanding of things quantum computational --- or even just plain quantum." Barbara Terhal, IBM T.J. Watson Research Center for PHYSICS TODAY

Pre-Publication Endorsement:
"... will be a standard for instruction and reference for years to come. ... The book is suffused with Mermin's unique knowledge of the history of modern physics, and has some of the most captivating writing to be found in a college textbook."
David DiVincenzo, IBM T. J. Watson Research Center

Pre-Publication Endorsement:
"... a gentle introduction to quantum computation especially aimed at an audience of computer scientists and mathematicians. ... Mermin has always been an entertaining and comprehensible writer, and continues to be in this book. I expect it to become the definitive introduction to this material for non-physicists."
Peter Shor, Massachusetts Institute of Technology

Pre-Publication Endorsement:
"... Mermin's lucid prose and gentle humor cajole [students] toward a sound intuition for what it all means, not an easy task for a subject superficially so counterintuitive."

Charles Bennett, IBM T. J. Watson Research Center

Pre-Publication Endorsement:
"This is one of the finest books in the rapidly growing field of quantum information. Almost every page contains a unique insight or a novel interpretation. David Mermin has once again demonstrated his legendary pedagogical skills to produce a classic."
Lov Grover, Bell Labs

About the Author
N. David Mermin is Horace White Professor of Physics Emeritus at Cornell University. He has received the Lilienfeld Prize of the American Physical Society and the Klopsteg Award of the American Association of Physics Teachers. He is a member of the U. S. National Academy of Sciences and the American Academy of Arts and Sciences. Professor Mermin has written on quantum foundational issues for several decades, and is known for the clarity and wit of his scientific writings. Among his other books are Solid State Physics (with N. W. Ashcroft, Thomson Learning 1976), Boojums all the Way Through (Cambridge University Press 1990), and It's about Time: Understanding Einstein's Relativity (Princeton University Press 2005).

Customer Reviews

elegant explanations
Mermin is perhaps best known as the co-author of 'Solid State Physics', a longstanding text of its subject. But his interests are diverse, and one of these is presented here. He explains the intriguing use of quantum computing. Starting with the concept of a Qbit.

The text assumes you've done some non-relativistic quantum mechanics. After all, the entire subject is based on quantum effects producing different results than traditional computing. You should know the bra and ket notation, that was first introduced by Dirac. This notation is amazingly concise and pervades the text. It is probably fair to say that 90% of the discussion uses this notation.

The derivations are elegant and surprisingly simple, compared to the intricacies of other applications of quantum mechanics. There is relatively little discussion of experimental methods. This is primarily a theoretical text.

One conclusion is that this field is young. No serious computations are yet capable, compared to those on computers using traditional classical physics.