Dualities of dihedral and generalised quaternion codes and applications to quantum codes
Abstract
Let Fq be a finite field of q elements, for some prime power q, and let G be a finite group. A (left) group code, or simply a G-code, is a (left) ideal of the group algebra Fq[G]. In this paper, we provide a complete algebraic description for the hermitian dual code of any Dn-code over Fq2, where Dn is a dihedral group of order 2n with n not divisible by char(Fq2), through a suitable Wedderburn-Artin's decomposition of the group algebra Fq2[Dn], and we determine all distinct hermitian self-orthogonal Dn-codes over Fq2. We also present a thorough representation of the euclidean dual code of any Qn-code over Fq, where Qn is a generalised quaternion group of order 4n not divisible by char(Fq), via the Wedderburn-Artin's decomposition of the group algebra Fq[Qn]. In particular, since the semisimple group algebras Fq2[Qn] and Fq2[D2n] are isomorphic, then the hermitian dual code of any Qn-code has also been fully described. As application of the hermitian dualities computed, we give a systematic construction, via the structure of the group algebra, to obtain quantum error-correcting codes, and in fact we rebuild some already known optimal quantum codes with this methodical approach.
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