Approximability of Optimization Problems through Adiabatic Quantum Computation (Record no. 85171)
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fixed length control field | 04576nam a22005175i 4500 |
001 - CONTROL NUMBER | |
control field | 978-3-031-02519-8 |
005 - DATE AND TIME OF LATEST TRANSACTION | |
control field | 20240730163951.0 |
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fixed length control field | 220601s2014 sz | s |||| 0|eng d |
020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
ISBN | 9783031025198 |
-- | 978-3-031-02519-8 |
082 04 - CLASSIFICATION NUMBER | |
Call Number | 510 |
100 1# - AUTHOR NAME | |
Author | Cruz-Santos, William. |
245 10 - TITLE STATEMENT | |
Title | Approximability of Optimization Problems through Adiabatic Quantum Computation |
250 ## - EDITION STATEMENT | |
Edition statement | 1st ed. 2014. |
300 ## - PHYSICAL DESCRIPTION | |
Number of Pages | XV, 97 p. |
490 1# - SERIES STATEMENT | |
Series statement | Synthesis Lectures on Quantum Computing, |
505 0# - FORMATTED CONTENTS NOTE | |
Remark 2 | Preface -- Acknowledgments -- Introduction -- Approximability of NP-hard Problems -- Adiabatic Quantum Computing -- Efficient Hamiltonian Construction -- AQC for Pseudo-Boolean Optimization -- A General Strategy to Solve NP-Hard Problems -- Conclusions -- Bibliography -- Authors' Biographies. |
520 ## - SUMMARY, ETC. | |
Summary, etc | The adiabatic quantum computation (AQC) is based on the adiabatic theorem to approximate solutions of the Schrödinger equation. The design of an AQC algorithm involves the construction of a Hamiltonian that describes the behavior of the quantum system. This Hamiltonian is expressed as a linear interpolation of an initial Hamiltonian whose ground state is easy to compute, and a final Hamiltonian whose ground state corresponds to the solution of a given combinatorial optimization problem. The adiabatic theorem asserts that if the time evolution of a quantum system described by a Hamiltonian is large enough, then the system remains close to its ground state. An AQC algorithm uses the adiabatic theorem to approximate the ground state of the final Hamiltonian that corresponds to the solution of the given optimization problem. In this book, we investigate the computational simulation of AQC algorithms applied to the MAX-SAT problem. A symbolic analysis of the AQC solution is given in order to understand the involved computational complexity of AQC algorithms. This approach can be extended to other combinatorial optimization problems and can be used for the classical simulation of an AQC algorithm where a Hamiltonian problem is constructed. This construction requires the computation of a sparse matrix of dimension 2n × 2n, by means of tensor products, where n is the dimension of the quantum system. Also, a general scheme to design AQC algorithms is proposed, based on a natural correspondence between optimization Boolean variables and quantum bits. Combinatorial graph problems are in correspondence with pseudo-Boolean maps that are reduced in polynomial time to quadratic maps. Finally, the relation among NP-hard problems is investigated, as well as its logical representability, and is applied to the design of AQC algorithms. It is shown that every monadic second-order logic (MSOL) expression has associated pseudo-Boolean maps that can be obtained by expanding the given expression, and also can be reduced to quadratic forms. Table of Contents: Preface / Acknowledgments / Introduction / Approximability of NP-hard Problems / Adiabatic Quantum Computing / Efficient Hamiltonian Construction / AQC for Pseudo-Boolean Optimization / A General Strategy to Solve NP-Hard Problems / Conclusions / Bibliography / Authors' Biographies. |
700 1# - AUTHOR 2 | |
Author 2 | Morales-Luna, Guillermo. |
856 40 - ELECTRONIC LOCATION AND ACCESS | |
Uniform Resource Identifier | https://doi.org/10.1007/978-3-031-02519-8 |
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Koha item type | eBooks |
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-- | Springer International Publishing : |
-- | Imprint: Springer, |
-- | 2014. |
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-- | text |
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-- | computer |
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-- | rdamedia |
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-- | online resource |
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-- | text file |
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650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Mathematics. |
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Quantum computers. |
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Quantum physics. |
650 14 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Mathematics. |
650 24 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Quantum Computing. |
650 24 - SUBJECT ADDED ENTRY--SUBJECT 1 | |
-- | Quantum Physics. |
830 #0 - SERIES ADDED ENTRY--UNIFORM TITLE | |
-- | 1945-9734 |
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-- | ZDB-2-SXSC |
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