English

Analysis of Sequential Decoding Complexity Using the Berry-Esseen Inequality

Information Theory 2007-08-20 v2 math.IT

Abstract

his study presents a novel technique to estimate the computational complexity of sequential decoding using the Berry-Esseen theorem. Unlike the theoretical bounds determined by the conventional central limit theorem argument, which often holds only for sufficiently large codeword length, the new bound obtained from the Berry-Esseen theorem is valid for any blocklength. The accuracy of the new bound is then examined for two sequential decoding algorithms, an ordering-free variant of the generalized Dijkstra's algorithm (GDA)(or simplified GDA) and the maximum-likelihood sequential decoding algorithm (MLSDA). Empirically investigating codes of small blocklength reveals that the theoretical upper bound for the simplified GDA almost matches the simulation results as the signal-to-noise ratio (SNR) per information bit (γb\gamma_b) is greater than or equal to 8 dB. However, the theoretical bound may become markedly higher than the simulated average complexity when γb\gamma_b is small. For the MLSDA, the theoretical upper bound is quite close to the simulation results for both high SNR (γb6\gamma_b\geq 6 dB) and low SNR (γb2\gamma_b\leq 2 dB). Even for moderate SNR, the simulation results and the theoretical bound differ by at most \makeblue{0.8} on a log10\log_{10} scale.

Keywords

Cite

@article{arxiv.cs/0701026,
  title  = {Analysis of Sequential Decoding Complexity Using the Berry-Esseen Inequality},
  author = {Po-Ning Chen and Yunghsiang S. Han and Carlos R. P. Hartmann and Hong-Bin Wu},
  journal= {arXiv preprint arXiv:cs/0701026},
  year   = {2007}
}

Comments

Submitted to the IEEE Trans. on Information Theory, 30 pages, 9 figures