English

Capacity Approaching Coding for Low Noise Interactive Quantum Communication, Part I: Large Alphabets

Quantum Physics 2020-01-10 v1 Computational Complexity Data Structures and Algorithms Information Theory math.IT

Abstract

We consider the problem of implementing two-party interactive quantum communication over noisy channels, a necessary endeavor if we wish to fully reap quantum advantages for communication. For an arbitrary protocol with nn messages, designed for a noiseless qudit channel over a poly(n)\mathrm{poly}(n) size alphabet, our main result is a simulation method that fails with probability less than 2Θ(nϵ)2^{-\Theta(n\epsilon)} and uses a qudit channel over the same alphabet n(1+Θ(ϵ))n\left(1+\Theta \left(\sqrt{\epsilon}\right)\right) times, of which an ϵ\epsilon fraction can be corrupted adversarially. The simulation is thus capacity achieving to leading order, and we conjecture that it is optimal up to a constant factor in the ϵ\sqrt{\epsilon} term. Furthermore, the simulation is in a model that does not require pre-shared resources such as randomness or entanglement between the communicating parties. Our work improves over the best previously known quantum result where the overhead is a non-explicit large constant [Brassard et al., FOCS'14] for low ϵ\epsilon.

Keywords

Cite

@article{arxiv.2001.02818,
  title  = {Capacity Approaching Coding for Low Noise Interactive Quantum Communication, Part I: Large Alphabets},
  author = {Debbie Leung and Ashwin Nayak and Ala Shayeghi and Dave Touchette and Penghui Yao and Nengkun Yu},
  journal= {arXiv preprint arXiv:2001.02818},
  year   = {2020}
}

Comments

94 pages, 7 figures

R2 v1 2026-06-23T13:06:34.662Z