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Playing games with multiple access channels

Author

Listed:
  • Felix Leditzky

    (University of Colorado/NIST
    University of Colorado)

  • Mohammad A. Alhejji

    (University of Colorado/NIST
    University of Colorado)

  • Joshua Levin

    (University of Colorado/NIST
    University of Colorado)

  • Graeme Smith

    (University of Colorado/NIST
    University of Colorado
    University of Colorado)

Abstract

Communication networks have multiple users, each sending and receiving messages. A multiple access channel (MAC) models multiple senders transmitting to a single receiver, such as the uplink from many mobile phones to a single base station. The optimal performance of a MAC is quantified by a capacity region of simultaneously achievable communication rates. We study the two-sender classical MAC, the simplest and best-understood network, and find a surprising richness in both a classical and quantum context. First, we find that quantum entanglement shared between senders can substantially boost the capacity of a classical MAC. Second, we find that optimal performance of a MAC with bounded-size inputs may require unbounded amounts of entanglement. Third, determining whether a perfect communication rate is achievable using finite-dimensional entanglement is undecidable. Finally, we show that evaluating the capacity region of a two-sender classical MAC is in fact NP-hard.

Suggested Citation

  • Felix Leditzky & Mohammad A. Alhejji & Joshua Levin & Graeme Smith, 2020. "Playing games with multiple access channels," Nature Communications, Nature, vol. 11(1), pages 1-5, December.
    • Handle: RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-15240-w
    DOI: 10.1038/s41467-020-15240-w
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