What question did this study set out to answer?

The aim is to classify self-dual matrix codes over Galois rings, extending previous theories on finite fields.

April 22, 2026Open Access

Self-dual matrix codes over Galois rings

Key Points

The aim is to classify self-dual matrix codes over Galois rings, extending previous theories on finite fields.
Characterization of linear matrix-equivalence maps for matrices over Galois rings.
Elementary proof using Morrison’s method for matrices of varying sizes.
Classification of self-dual matrix codes over \(\mathbb{Z}_4\) for small sizes.
An alternative proof for matrix equivalence as defined by McDonald for square matrices.
Characterization of maps that commute with dual operations.
Successful classification of small self-dual matrix codes over \(\mathbb{Z}_4\).

Abstract

In this paper, we extend the classification theory of self-dual matrix codes over finite fields due to Morrison to Galois rings. That is, we characterize a linear matrix-equivalence map defined as an S-automorphism of the module of matrices over Galois rings which preserves types of all matrices. This characterization has been already given by McDonald in the case for square matrices. In this paper, we present an alternative elementary proof of this result for matrices of arbitrary size using Morrison’s method. Also we characterize the subset of linear matrix-equivalence maps which commute with the operation taking the dual, and we define an equivalence of self-dual matrix codes by the maps. Finally using the equivalence, we classify self-dual matrix codes over { {Z}}₄ with small sizes.

Bookmark

View Full Paper