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Main Authors: Wang, Shukai, Fan, Cuiling, Tang, Chunming, Zhou, Zhengchun
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.07730
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author Wang, Shukai
Fan, Cuiling
Tang, Chunming
Zhou, Zhengchun
author_facet Wang, Shukai
Fan, Cuiling
Tang, Chunming
Zhou, Zhengchun
contents The binary asymmetric channel is a model for practical communication systems where the error probabilities for symbol transitions $0\rightarrow 1$ and $1\rightarrow0$ differ substantially. In this paper, we introduce the notion of asymmetric Hamming bidistance (AHB) and its two-dimensional distribution, which separately captures directional discrepancies between codewords. This finer characterization enables a more discriminative analysis of decoding the error probabilities for maximum-likelihood decoding (MLD), particularly when conventional measures, such as weight distributions and existing discrepancy-based bounds, fail to distinguish code performance. Building on this concept, we derive a new upper bound on the average error probability for binary codes under MLD and show that, in general, it is incomparable with the two existing bounds derived by Cotardo and Ravagnani (IEEE Trans. Inf. Theory, 68 (5), 2022). To demonstrate its applicability, we compute the complete AHB distributions for several families of codes, including two-weight and three-weight projective codes (with the zero codeword removed) via strongly regular graphs and 3-class association schemes, as well as nonlinear codes constructed from symmetric balanced incomplete block designs (SBIBDs).
format Preprint
id arxiv_https___arxiv_org_abs_2604_07730
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publishDate 2026
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spellingShingle The Asymmetric Hamming Bidistance and Distributions over Binary Asymmetric Channels
Wang, Shukai
Fan, Cuiling
Tang, Chunming
Zhou, Zhengchun
Information Theory
The binary asymmetric channel is a model for practical communication systems where the error probabilities for symbol transitions $0\rightarrow 1$ and $1\rightarrow0$ differ substantially. In this paper, we introduce the notion of asymmetric Hamming bidistance (AHB) and its two-dimensional distribution, which separately captures directional discrepancies between codewords. This finer characterization enables a more discriminative analysis of decoding the error probabilities for maximum-likelihood decoding (MLD), particularly when conventional measures, such as weight distributions and existing discrepancy-based bounds, fail to distinguish code performance. Building on this concept, we derive a new upper bound on the average error probability for binary codes under MLD and show that, in general, it is incomparable with the two existing bounds derived by Cotardo and Ravagnani (IEEE Trans. Inf. Theory, 68 (5), 2022). To demonstrate its applicability, we compute the complete AHB distributions for several families of codes, including two-weight and three-weight projective codes (with the zero codeword removed) via strongly regular graphs and 3-class association schemes, as well as nonlinear codes constructed from symmetric balanced incomplete block designs (SBIBDs).
title The Asymmetric Hamming Bidistance and Distributions over Binary Asymmetric Channels
topic Information Theory
url https://arxiv.org/abs/2604.07730