• DocumentCode
    825056
  • Title

    Entanglement-assisted capacity of a quantum channel and the reverse Shannon theorem

  • Author

    Bennett, Charles H. ; Shor, Peter W. ; Smolin, John A. ; Thapliyal, Ashish V.

  • Author_Institution
    IBM Thomas J. Watson Res. Center, Yorktown Heights, NY, USA
  • Volume
    48
  • Issue
    10
  • fYear
    2002
  • fDate
    10/1/2002 12:00:00 AM
  • Firstpage
    2637
  • Lastpage
    2655
  • Abstract
    The entanglement-assisted classical capacity of a noisy quantum channel (CE) is the amount of information per channel use that can be sent over the channel in the limit of many uses of the channel, assuming that the sender and receiver have access to the resource of shared quantum entanglement, which may be used up by the communication protocol. We show that the capacity CE is given by an expression parallel to that for the capacity of a purely classical channel: i.e., the maximum, over channel inputs ρ, of the entropy of the channel input plus the entropy of the channel output minus their joint entropy, the latter being defined as the entropy of an entangled purification of ρ after half of it has passed through the channel. We calculate entanglement-assisted capacities for two interesting quantum channels, the qubit amplitude damping channel and the bosonic channel with amplification/attenuation and Gaussian noise. We discuss how many independent parameters are required to completely characterize the asymptotic behavior of a general quantum channel, alone or in the presence of ancillary resources such as prior entanglement. In the classical analog of entanglement-assisted communication - communication over a discrete memoryless channel (DMC) between parties who share prior random information - we show that one parameter is sufficient, i.e., that in the presence of prior shared random information, all DMCs of equal capacity can simulate one another with unit asymptotic efficiency.
  • Keywords
    Gaussian noise; channel capacity; entropy; memoryless systems; protocols; quantum communication; Gaussian noise; amplification/attenuation; asymptotic behavior; asymptotic efficiency; bosonic channel; channel entropy; communication protocol; discrete memoryless channel; entanglement-assisted capacity; entanglement-assisted communication; information per channel; joint entropy; noisy quantum channel; qubit amplitude damping channel; reverse Shannon theorem; shared quantum entanglement; shared random information; Access protocols; Attenuation; Damping; Entropy; Gaussian noise; Memoryless systems; Monte Carlo methods; Purification; Quantum entanglement; Quantum mechanics;
  • fLanguage
    English
  • Journal_Title
    Information Theory, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9448
  • Type

    jour

  • DOI
    10.1109/TIT.2002.802612
  • Filename
    1035117