The paper starts by exploring the foundational structure of the serial ring R = R[x1, ..., xs]/⟨t1(x1), ..., ts(xs)⟩, where R is a finite commutative chain ring and each ti(xi) is a monic square-free polynomial. It is shown that R is a serial ring and a principal ideal Frobenius ring.
The authors then investigate polycyclic codes over R and establish that any polycyclic code C over R can be decomposed into a direct sum of polycyclic codes Ci over chain rings Ri. They define quasi-s-dimensional polycyclic (QsDP) codes and prove that polycyclic codes over R are equivalent to f(x)-polycyclic-QsDP codes.
The paper further explores the concept of annihilator dual for polycyclic codes over R and revises the existing statement about annihilator self-dual polycyclic codes. It is shown that a polycyclic code ⟨g(x)⟩ is annihilator self-dual if and only if f(x) = ag2(x) for some unit element a in R.
Finally, the authors present an annihilator CSS construction to derive quantum codes from annihilator dual-preserving f(x)-polycyclic codes over R, where g(x) divides f(x).
A otro idioma
del contenido fuente
arxiv.org
Ideas clave extraídas de
by Maryam Bajal... a las arxiv.org 04-17-2024
https://arxiv.org/pdf/2404.10452.pdfConsultas más profundas