Quantum information, computation and communication / (Record no. 1613)
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| 000 -LEADER | |
|---|---|
| fixed length control field | 04113cam a22001934a 4500 |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
| International Standard Book Number | 9781107014466 (hardback) |
| 040 ## - CATALOGING SOURCE | |
| Transcribing agency | CCUS |
| 082 00 - DEWEY DECIMAL CLASSIFICATION NUMBER | |
| Classification number | 004.1 |
| Item number | JON/Q |
| 100 1# - MAIN ENTRY--PERSONAL NAME | |
| Personal name | Jones, J. A. |
| 245 10 - TITLE STATEMENT | |
| Title | Quantum information, computation and communication / |
| Statement of responsibility, etc. | Jonathan A. Jones, Dieter Jaksch. |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
| Place of publication, distribution, etc. | New York : |
| Name of publisher, distributor, etc. | Cambridge University Press, |
| Date of publication, distribution, etc. | 2012. |
| 300 ## - PHYSICAL DESCRIPTION | |
| Extent | viii, 200 p. |
| Dimensions | 26 cm. |
| 504 ## - BIBLIOGRAPHY, ETC. NOTE | |
| Bibliography, etc | includes index |
| 505 8# - FORMATTED CONTENTS NOTE | |
| Formatted contents note | 1 Quantum bits and quantum gates<br/>1.1 The Bloch sphere<br/>Part I Quantum information<br/>1.2 Density matrices and Pauli matrices<br/>1.3 Quantum logic gates<br/>1.4 Quantum networks<br/>1.5 Initialization and measurement<br/>1.6 Experimental methods<br/>Further reading<br/>Exercises<br/>2 An atom in a laser field<br/>2.1 Time-dependent systems<br/>2.2 Sudden jumps<br/>2.3 Oscillating fields<br/>2.4 Time-dependent perturbation theory<br/>2.5 Rabi flopping and Fermi's Golden Rule<br/>2.6 Raman transitions<br/>2.7 Rabi flopping and Ramsey fnnges<br/>2.8 Measurement and initialization<br/>Further reading<br/>Exercises<br/>3 Spins in magnetic fields<br/>3.1 The nuclear spin Hamiltonian<br/>3.2 The rotating frame<br/>3.3 On- and ofF-resonance excitation<br/>3.4 The vector model<br/>3.5 Spin echoes<br/>3.6 Measurement and initialization<br/>Further reading<br/>Exercises<br/>4 Photon techniques<br/>4.1 Spatial encoding<br/>4.2 Polarization encoding<br/>4.3 Single-photon sources and detectors<br/>4.4 Conventions<br/>Further reading<br/>Exercises<br/>5 Two qublts and beyond<br/>5.1 Direct products<br/>5.2 Matrix forms<br/>5.3 Two-qubit gates<br/>5.4 Networks and circuits<br/>5.5 Entangled states<br/>Further reading<br/>Exercises<br/>6 Measurement and entanglement<br/>6.1 Measuring a single qubit<br/>6.2 Ensembles and the no-cloning theorem<br/>6.3 Fidelity<br/>6.4 Local operations and classical communication<br/>Further reading<br/>Exercises<br/>7 Principles of quantum computing<br/>7.1 Reversible computing<br/>7.2 Quantum parallelism<br/>7.3 Getting the answer out<br/>7.4 The DiVincenzo criteria<br/>Further reading<br/>Exercises<br/>8 Elementary quantum algorithms<br/>8.1 Deutsch's algorithm<br/>8.2 Why it works<br/>8.3 Circuit identities<br/>Part II Quantum computation<br/>8.4 Deutsch's algorithm and interferometry<br/>8.5 Grover's algorithm<br/>8.6 Error correction<br/>8.7 Decoherence-firee subspaces<br/>Further reading<br/>Exercises<br/>9 More advanced quantum algorithms<br/>9.1 The Deutsch-Jozsa algorithm<br/>9.2 The Bemstein-Vazirani algorithm<br/>9.3 Deutsch-Jozsa and period finding<br/>9.4 Fourier transforms and quantum factoring<br/>9.5 Graver's algorithm<br/>9.6 Generalizing Grover's algorithm<br/>9.7 Quantum simulation<br/>9.8 Experimental implementations<br/>Further reading<br/>Exercises<br/>10 Trapped atoms and Ions<br/>10.1 Ion traps<br/>10.2 Atom traps and optical lattices<br/>10.3 Initialization<br/>10.4 Decoherence<br/>10.5 Universal logic<br/>10.6 Two-qubit gates with ions<br/>10.7 Two-qubit gates with atoms<br/>10.8 Massive entanglement<br/>10.9 Readout<br/>Further reading<br/>Exercises<br/>11 Nuclear magnetic resonance<br/>11.1 Qubits<br/>11.2 Initialization<br/>11.3 Decoherence<br/>11.4 Universal logic<br/>11.5 Readout<br/>Further reading<br/>Exercises<br/>12 Large-scale quantum computers<br/>12.1 Trapped ions<br/>12.2 Optical lattices<br/>12.3 NMR<br/>12.4 Other approaches<br/>Further reading<br/>13 Basics of Information theory<br/>13.1 Classical information<br/>Part III Quantum communication<br/>13.2 Mutual information<br/>13.3 The communication channel<br/>13.4 Connection to statistical physics<br/>Further reading<br/>Exercises<br/>14 Quantum information<br/>14.1 The density operator<br/>14.2 Global and local measurements<br/>14.3 Information content of a density operator<br/>14.4 Joint entropy and mutual information<br/>14.5 Quantum channels<br/>Further reading<br/>Exercises<br/>15 Quantum communication<br/>15.1 Parametric down-conversion<br/>15.2 Quantum dense coding<br/>15.3 Quantum teleportation<br/>15.4 Entanglement swapping<br/>Further reading<br/>Exercises<br/>16 Testing ERR<br/>16.1 Bell inequalities<br/>16.2 GHZ states<br/>Further reading<br/>Exercises<br/>17 Quantum cryptography<br/>17.1 One-time pads and the Vernam cipher<br/>17.2 The BB84 protocol<br/>17.3 The Ekert91 protocol<br/>17.4 Experimental setups<br/>Further reading<br/>Exercises |
| 650 #0 - SUBJECT | |
| Keyword | Quantum Computers |
| 650 #0 - SUBJECT | |
| Keyword | Information theory in physics |
| 650 #7 - SUBJECT | |
| Keyword | SCIENCE / Quantum Theory |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
| Koha item type | General Books |
| Withdrawn status | Lost status | Damaged status | Not for loan | Home library | Current library | Shelving location | Date acquired | Full call number | Accession number | Date last seen | Date last checked out | Koha item type |
|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Central Library, Sikkim University | Central Library, Sikkim University | General Book Section | 31/05/2016 | 004.1 JON/Q | P43319 | 14/07/2018 | 14/07/2018 | General Books |