Fault-Tolerant Coding for Entanglement-Assisted Communication
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Fault-Tolerant Coding for Entanglement-Assisted Communication. / Belzig, Paula; Christandl, Matthias; Müller-hermes, Alexander.
2023 IEEE International Symposium on Information Theory (ISIT). IEEE, 2023. p. 84-89.Research output: Chapter in Book/Report/Conference proceeding › Article in proceedings › Research › peer-review
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TY - GEN
T1 - Fault-Tolerant Coding for Entanglement-Assisted Communication
AU - Belzig, Paula
AU - Christandl, Matthias
AU - Müller-hermes, Alexander
PY - 2023
Y1 - 2023
N2 - Channel capacities quantify the optimal rates of sending information reliably over noisy channels. Usually, the study of capacities assumes that the circuits which sender and receiver use for encoding and decoding consist of perfectly noiseless gates. In the case of communication over quantum channels, however, this assumption is widely believed to be unrealistic, even in the long-term, due to the fragility of quantum information, which is affected by the process of decoherence. Christandl and Müller-Hermes have therefore initiated the study of fault-tolerant channel coding for quantum channels, i.e. coding schemes where encoder and decoder circuits are affected by noise, and have used techniques from fault-tolerant quantum computing to establish coding theorems for sending classical and quantum information in this scenario. Here, we extend these methods to the case of entanglement-assisted communication, in particular proving that the fault-tolerant capacity approaches the usual capacity when the gate error approaches zero. A main tool, which might be of independent interest, is the introduction of fault-tolerant entanglement distillation. We furthermore focus on the modularity of the techniques used, so that they can be easily adopted in other fault-tolerant communication scenarios.
AB - Channel capacities quantify the optimal rates of sending information reliably over noisy channels. Usually, the study of capacities assumes that the circuits which sender and receiver use for encoding and decoding consist of perfectly noiseless gates. In the case of communication over quantum channels, however, this assumption is widely believed to be unrealistic, even in the long-term, due to the fragility of quantum information, which is affected by the process of decoherence. Christandl and Müller-Hermes have therefore initiated the study of fault-tolerant channel coding for quantum channels, i.e. coding schemes where encoder and decoder circuits are affected by noise, and have used techniques from fault-tolerant quantum computing to establish coding theorems for sending classical and quantum information in this scenario. Here, we extend these methods to the case of entanglement-assisted communication, in particular proving that the fault-tolerant capacity approaches the usual capacity when the gate error approaches zero. A main tool, which might be of independent interest, is the introduction of fault-tolerant entanglement distillation. We furthermore focus on the modularity of the techniques used, so that they can be easily adopted in other fault-tolerant communication scenarios.
U2 - 10.1109/ISIT54713.2023.10206950
DO - 10.1109/ISIT54713.2023.10206950
M3 - Article in proceedings
SP - 84
EP - 89
BT - 2023 IEEE International Symposium on Information Theory (ISIT)
PB - IEEE
T2 - 2023 IEEE International Symposium on Information Theory (ISIT)
Y2 - 25 June 2023 through 30 June 2023
ER -
ID: 362900561