English

Error Exponents for Variable-length Block Codes with Feedback and Cost Constraints

Information Theory 2020-01-03 v1 math.IT

Abstract

Variable-length block-coding schemes are investigated for discrete memoryless channels with ideal feedback under cost constraints. Upper and lower bounds are found for the minimum achievable probability of decoding error Pe,minP_{e,\min} as a function of constraints R,\AVR, \AV, and τˉ\bar \tau on the transmission rate, average cost, and average block length respectively. For given RR and \AV\AV, the lower and upper bounds to the exponent (lnPe,min)/τˉ-(\ln P_{e,\min})/\bar \tau are asymptotically equal as τˉ\bar \tau \to \infty. The resulting reliability function, limτˉ(lnPe,min)/τˉ\lim_{\bar \tau\to \infty} (-\ln P_{e,\min})/\bar \tau, as a function of RR and \AV\AV, is concave in the pair (R,\AV)(R, \AV) and generalizes the linear reliability function of Burnashev to include cost constraints. The results are generalized to a class of discrete-time memoryless channels with arbitrary alphabets, including additive Gaussian noise channels with amplitude and power constraints.

Keywords

Cite

@article{arxiv.cs/0612097,
  title  = {Error Exponents for Variable-length Block Codes with Feedback and Cost Constraints},
  author = {B. Nakiboglu and R. G. Gallager},
  journal= {arXiv preprint arXiv:cs/0612097},
  year   = {2020}
}