TY - JOUR
T1 - Random quantum codes from gaussian ensembles and an uncertainty relation
AU - Hayden, Patrick
AU - Shor, Peter W.
AU - Winter, Andreas
N1 - Funding Information:
PH is supported by the Canada Research Chairs program, CIFAR, FQRNT, MITACS, NSERC and QuantumWorks. He is also grateful to the DAMTP in Cambridge for their hospitality. PWS is partially supported by the W. M. Keck Foundation Center for Extreme Quantum Information Theory, and through the National Science Foundation through grant CCF-0431787. AW is supported by the U.K. EPSRC (project “QIP IRC” and an Advanced Research Fellowship), by a Royal Society Wolfson Merit Award, and the EC, IP “QAP”. The Centre for Quantum Technologies is funded by the Singapore Ministry of Education and the National Research Foundation as part of the Research Centres of Excellence programme.
PY - 2008/3
Y1 - 2008/3
N2 - Using random Gaussian vectors and an information-uncertainty relation, we give a proof that the coherent information is an achievable rate for entanglement transmission through a noisy quantum channel. The codes are random subspaces selected according to the Haar measure, but distorted as a function of the senders input density operator. Using large deviations techniques, we show that classical data transmitted in either of two Fourier-conjugate bases for the coding subspace can be decoded with low probability of error. A recently discovered information-uncertainty relation then implies that the quantum mutual information for entanglement encoded into the subspace and transmitted through the channel will be high. The monogamy of quantum correlations finally implies that the environment of the channel cannot be significantly coupled to the entanglement which, concluding, ensures the existence of a decoding by the receiver.
AB - Using random Gaussian vectors and an information-uncertainty relation, we give a proof that the coherent information is an achievable rate for entanglement transmission through a noisy quantum channel. The codes are random subspaces selected according to the Haar measure, but distorted as a function of the senders input density operator. Using large deviations techniques, we show that classical data transmitted in either of two Fourier-conjugate bases for the coding subspace can be decoded with low probability of error. A recently discovered information-uncertainty relation then implies that the quantum mutual information for entanglement encoded into the subspace and transmitted through the channel will be high. The monogamy of quantum correlations finally implies that the environment of the channel cannot be significantly coupled to the entanglement which, concluding, ensures the existence of a decoding by the receiver.
UR - https://www.scopus.com/pages/publications/53449093272
U2 - 10.1142/S1230161208000079
DO - 10.1142/S1230161208000079
M3 - Article
AN - SCOPUS:53449093272
SN - 1230-1612
VL - 15
SP - 71
EP - 89
JO - Open Systems and Information Dynamics
JF - Open Systems and Information Dynamics
IS - 1
ER -