Introduction to error correcting codes in quantum computers

Salas-Peralta, P. J.

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Revista mexicana de física E

versión impresa ISSN 1870-3542

Rev. mex. fís. E vol.52 no.2 México dic. 2006

Enseñanza

Introduction to error correcting codes in quantum computers

P. J. Salas-Peralta

Departamento de Tecnologías Especiales Aplicadas a la Telecomunicación, Universidad Politécnica de Madrid, Ciudad Universitaria s/n, 28040 Madrid, e-mail: psalas@etsit.upm.es

Recibido el 25 de octubre de 2005;
aceptado el 7 de marzo de 2006

Abstract

The goal of this paper is to review the theoretical basis for achieving a faithful quantum information transmission and processing in the presence of noise. Initially, encoding and decoding, implementing gates and quantum error correction will be considered error-free. Finally, we shall relax this non-realistic assumption, introducing the quantum fault-tolerant concept. The existence of an error threshold permits us to conclude that there is no physical law preventing a quantum computer from being built. An error model based on the depolarising channel will be able to provide a simple estimate of the storage or memory computation error threshold: η_th < 5.2 10^-5. The encoding is made by means of the [[7,1,3]] Calderbank-Shor-Steane quantum code, and Shor's fault-tolerant method is used to measure the stabiliser's generators.

Keywords: Quantum error correcting codes; decoherence; quantum computation.

Resumen

El objetivo de este artículo es la revisión de los fundamentos teóricos que permiten una correcta transmisión y procesado de la información cuántica en presencia de ruido. Inicialmente, los procesos de codificación, decodificación, aplicación de puertas y corrección de errores se consideraran sin error. Finalmente relajaremos esta consideración no realista, lo que conducirá al concepto de tolerancia a fallos. La existencia de un umbral de error permite concluir que no hay ninguna ley física que impida construir un ordenador cuántico. Mediante un modelo de error basado en un canal despolarizante, se hará una estimación simple para el umbral de los errores de memoria: η_th < 5.2 10^-5. La codificación se realiza mediante un código cuántico [[7,1,3]] de Calderbank-Shor-Steane, y se usa el método de Shor tolerante a fallos para medir los generadores del estabilizador.

Descriptores: Códigos correctores de errores cuánticos; decoherencia; computación cuántica.

PACS: 0367-a; 0367Lx

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