On Hull-Variation Problem of Equivalent Linear Codes

Abstract

The intersection C C ( C Ch) of a linear code C and its Euclidean dual C (Hermitian dual Ch) is called the Euclidean (Hermitian) hull of this code. It is natural to consider the hull-variation problem when a linear code C is transformed to an equivalent code v · C. In this paper we introduce the maximal hull dimension as an invariant of a linear code with respect to the equivalent transformations. Then some basic properties of the maximal hull dimension are studied. We prove that for a nonnegative integer h satisfying 0 ≤ h ≤ n-1, a linear [2n, n]q self-dual code is equivalent to a linear h-dimension hull code. On the opposite direction we prove that a linear LCD code over F2s satisfying d≥ 2 and d ≥ 2 is equivalent to a linear one-dimension hull code under a weak condition. Several new families of LCD negacyclic codes and LCD BCH codes over F3 are also constructed. Our method can be applied to the generalized Reed-Solomon codes and the generalized twisted Reed-Solomon codes to construct arbitrary dimension hull MDS codes. Some new entanglement-assisted quantum error-correction (EAQEC) codes including MDS and almost MDS EAQEC codes are constructed. Many EAQEC codes over small fields are constructed from optimal Hermitian self-dual codes.