On the Maximum Size of Codes Under the Damerau-Levenshtein Metric

Abstract

The Damerau-Levenshtein distance between two sequences is the minimum number of operations (deletions, insertions, substitutions, and adjacent transpositions) required to convert one sequence into another. Notwithstanding a long history of this metric, research on error-correcting codes under this distance has remained limited. Recently, motivated by applications in DNA-based storage systems, Gabrys et al and Wang et al reinvigorated interest in this metric. In their works, some codes correcting both deletions and adjacent transpositions were constructed. However, theoretical upper bounds on code sizes under this metric have not yet been established. This paper seeks to establish upper bounds for code sizes in the Damerau-Levenshtein metric. Our results show that the code correcting one deletion and asymmetric adjacent transpositions proposed by Wang et al achieves optimal redundancy up to an additive constant.