Generalized Automorphisms of Channel Codes: Properties, Code Design, and a Decoder
Abstract
Low-density parity-check codes together with belief propagation (BP) decoding are known to be well-performing for large block lengths. However, for short block lengths there is still a considerable gap between the performance of the BP decoder and the maximum likelihood decoder. Different ensemble decoding schemes such as, e.g., the automorphism ensemble decoder (AED), can reduce this gap in short block length regime. We propose a generalized AED (GAED) that uses automorphisms according to the definition in linear algebra. Here, an automorphism of a vector space is defined as a linear, bijective self-mapping, whereas in coding theory self-mappings that are scaled permutations are commonly used. We show that the more general definition leads to an explicit joint construction of codes and automorphisms, and significantly enlarges the search space for automorphisms of existing linear codes. Furthermore, we prove the concept that generalized automorphisms can indeed be used to improve decoding. Additionally, we propose a code construction of parity check codes enabling the construction of codes with suitably designed automorphisms. Finally, we analyze the decoding performances of the GAED for some of our constructed codes.
Cite
@article{arxiv.2304.14379,
title = {Generalized Automorphisms of Channel Codes: Properties, Code Design, and a Decoder},
author = {Jonathan Mandelbaum and Holger Jäkel and Laurent Schmalen},
journal= {arXiv preprint arXiv:2304.14379},
year = {2023}
}
Comments
Accepted for presentation at International Symposium on Topics in Coding 2023 Included reviews: Changed naming of automorphism groups; Corrected typo in def. of GAUT; Preprocessing no longer as theorem; Smaller formatting changes; Results unchanged