Bounds and Constructions of Codes for Ordered Composite DNA Sequences
Abstract
This paper extends the foundational work of Dollma \emph{et al}. on codes for ordered composite DNA sequences. We consider the general setting with an alphabet of size and a resolution parameter , moving beyond the binary () case primarily studied previously. We investigate error-correcting codes for substitution errors and deletion errors under several channel models, including -composite error/deletion, -composite error/deletion, and the newly introduced --composite error/deletion model. We first establish equivalence relations among families of composite-error correcting codes (CECCs) and among families of composite-deletion correcting codes (CDCCs). This significantly reduces the number of distinct error-parameter sets that require separate analysis. We then derive novel and general upper bounds on the sizes of CECCs using refined sphere-packing arguments and probabilistic methods. These bounds together cover all values of parameters , , and . In contrast, previous bounds were only established for and limited choices of , and . For CDCCs, we generalize a known non-asymptotic upper bound for -CDCCs and then provide a cleaner asymptotic bound. On the constructive side, for any , we propose -CDCCs, -CDCCs and --CDCCs with near-optimal redundancies. These codes have efficient and systematic encoders. For substitution errors, we design the first explicit encoding and decoding algorithms for the binary -CECC constructed by Dollma \emph{et al}, and extend the approach to general . Furthermore, we give an improved construction of binary -CECCs, a construction of nonbinary -CECCs, and a construction of --CECCs. These constructions are also systematic.
Cite
@article{arxiv.2602.16406,
title = {Bounds and Constructions of Codes for Ordered Composite DNA Sequences},
author = {Zuo Ye and Yuling Li and Zhaojun Lan and Gennian Ge},
journal= {arXiv preprint arXiv:2602.16406},
year = {2026}
}
Comments
submitted