Self-dual codes with group actions and invariants

Abstract

In this paper, we define dual codes over arbitrary finite rings with respect to arbitrary bilinear forms and provide a generalization of Hayden's theorem (Bridges, Hall, and Hayden, 1981). Building on this foundation, we introduce the concept of G-dual codes for codes invariant under a permutation group G, referred to as G-codes. We then present several generalizations of Atsumi's MacWilliams identity (Atsumi, 1995; Chakraborty and Miezaki, 2023) for G-codes over finite rings with respect to general bilinear forms. Furthermore, we establish a G-analogue of the MacWilliams identity for G-full weight enumerators and introduce the notions of G-quadratic maps and G-representations for twisted modules, twisted rings, quadratic pairs, and form rings. By defining transformation groups for G-full weight enumerators, we extend the theory of Clifford--Weil groups (Nebe, Rains, and Sloane, 2004, 2006). Finally, we provide generalizations of Gleason-type theorems for these weight enumerators, demonstrating that the G-full weight enumerators of G-self-dual and G-isotropic codes are invariant under the Clifford--Weil groups and span the invariant subspaces of these groups.