English

Variable-Length Codes with Bursty Feedback

Information Theory 2023-06-27 v1 math.IT

Abstract

We study variable-length codes for point-to-point discrete memoryless channels with noiseless unlimited-rate feedback that occurs in LL bursts. We term such codes variable-length bursty-feedback (VLBF) codes. Unlike classical codes with feedback after each transmitted code symbol, bursty feedback fits better with protocols that employ sparse feedback after a packet is sent and also with half-duplex end devices that cannot transmit and listen to the channel at the same time. We present a novel non-asymptotic achievability bound for VLBF codes with LL bursts of feedback over any discrete memoryless channel. We numerically evaluate the bound over the binary symmetric channel (BSC). We perform optimization over the time instances at which feedback occurs for both our own bound and Yavas et al.'s non-asymptotic achievability bound for variable-length stop-feedback (VLSF) codes, where only a single bit is sent at each feedback instance. Our results demonstrate the advantages of richer feedback: VLBF codes significantly outperform VLSF codes at short blocklengths, especially as the error probability ϵ\epsilon decreases. Remarkably, for BSC(0.11) and error probability 101010^{-10}, our VLBF code with L=5L=5 and expected decoding time N400N\leq 400 outperforms the achievability bound given by Polyanskiy et al. for VLSF codes with L=L=\infty, and our VLBF code with L=3L=3.

Keywords

Cite

@article{arxiv.2306.13743,
  title  = {Variable-Length Codes with Bursty Feedback},
  author = {James Y. Chen and Recep Can Yavas and Victoria Kostina},
  journal= {arXiv preprint arXiv:2306.13743},
  year   = {2023}
}

Comments

Presented at ISIT 2023

R2 v1 2026-06-28T11:13:09.942Z