Numerical simulation of information recovery in quantum computers

A. L. Sanz; A. M. Steane; A. M. Steane; A. M. Steane; A. M. Steane; A. M. Steane; A. R. Calderbank; D. Gottesman; E. Knill; E. Knill; J. Preskill; P. J. Salas; P. W. Shor; R. Laflamme; W. G. Unruh; W. H. Zurek; W. K. Wooters

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Numerical simulation of information recovery in quantum computers

Authors: A. L. Sanz
A. M. Steane
A. M. Steane
A. M. Steane
A. M. Steane
A. M. Steane
A. R. Calderbank
D. Gottesman
E. Knill
E. Knill
J. Preskill
P. J. Salas
P. W. Shor
R. Laflamme
W. G. Unruh
W. H. Zurek
W. K. Wooters
Publication date: 11 July 2002
Publisher: 'American Physical Society (APS)'
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Abstract

Decoherence is the main problem to be solved before quantum computers can be built. To control decoherence, it is possible to use error correction methods, but these methods are themselves noisy quantum computation processes. In this work we study the ability of Steane's and Shor's fault-tolerant recovering methods, as well a modification of Steane's ancilla network, to correct errors in qubits. We test a way to measure correctly ancilla's fidelity for these methods, and state the possibility of carrying out an effective error correction through a noisy quantum channel, even using noisy error correction methods.Comment: 38 pages, Figures included. Accepted in Phys. Rev. A, 200

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