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A Beta-Beta Achievability Bound with Applications

Information Theory 2016-01-25 v1 math.IT

Abstract

A channel coding achievability bound expressed in terms of the ratio between two Neyman-Pearson β\beta functions is proposed. This bound is the dual of a converse bound established earlier by Polyanskiy and Verd\'{u} (2014). The new bound turns out to simplify considerably the analysis in situations where the channel output distribution is not a product distribution, for example due to a cost constraint or a structural constraint (such as orthogonality or constant composition) on the channel inputs. Connections to existing bounds in the literature are discussed. The bound is then used to derive 1) an achievability bound on the channel dispersion of additive non-Gaussian noise channels with random Gaussian codebooks, 2) the channel dispersion of the exponential-noise channel, 3) a second-order expansion for the minimum energy per bit of an AWGN channel, and 4) a lower bound on the maximum coding rate of a multiple-input multiple-output Rayleigh-fading channel with perfect channel state information at the receiver, which is the tightest known achievability result.

Keywords

Cite

@article{arxiv.1601.05880,
  title  = {A Beta-Beta Achievability Bound with Applications},
  author = {Wei Yang and Austin Collins and Giuseppe Durisi and Yury Polyanskiy and H. Vincent Poor},
  journal= {arXiv preprint arXiv:1601.05880},
  year   = {2016}
}

Comments

extended version of a paper submitted to ISIT 2016

R2 v1 2026-06-22T12:34:37.759Z