Abstract
A code over a group ring is defined to be a submodule of that group ring. For a code $C$ over a group ring $RG$, $C$ is said to be checkable if there is $v\in RG$ such that {$C=\{x\in RG: xv=0\}$}. In \cite{r2}, Jitman et al. introduced the notion of code-checkable group ring. We say that a group ring $RG$ is code-checkable if every ideal in $RG$ is a checkable code. In their paper, Jitman et al. gave a necessary and sufficient condition for the group ring $\mathbb{F}G$, when $\mathbb{F}$ is a finite field and $G$ is a finite abelian group, to be code-checkable. In this paper, we give some characterizations for code-checkable group rings for more general alphabet. For instance, a finite commutative group ring $RG$, with $R$ is semisimple, is code-checkable if and only if $G$ is $\pi'$-by-cyclic $\pi$; where $\pi$ is the set of noninvertible primes in $R$. Also, under suitable conditions, $RG$ turns out to be code-checkable if and only if it is pseudo-morphic.
Highlights
A code over a group ring is originally defined to be an ideal in the group algebra FG, where F is a finite field and G is a finite group
For a code C over a group ring RG, C is said to be checkable if there is v ∈ RG such that C = {x ∈ RG : xv = 0}
Codes from group-ring encoding are basically defined by considering a left R-submodule W of the group ring RG and any element u of RG, the right group-ring code C generated by u relative to W is the code defined by C = {xu : x ∈ W }
Summary
A code over a group ring is originally defined to be an ideal in the group algebra FG, where F is a finite field and G is a finite group. A zero-divisor code C is called checkable if there exists v ∈ RG such that C = {y ∈ RG : yv = 0}, that is y ∈ C if and only if yv = 0 In this case we say that v is a check element for the code C. The main question was about a characterization for code-checkable group rings. We focus on checkable codes, which are special case of codes from group ring encodings. A zero-divisor code is said to be checkable if it is a left annihilator for some element in the group ring. We present the result due to Jitman et al [6] in characterizing code-checkable group algebras.
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