English

Differential Goppa Codes

Algebraic Geometry 2026-03-05 v1 Information Theory math.IT

Abstract

Rosenbloom and Tsfasman, in their foundational work on the mm-metric, introduced algebraic-geometric codes defined by multiple points on a smooth projective curve XX. This construction involves a divisor GG and another divisor D=npiD=\sum n p_i, where pip_i are distinct rational points with pisupp(G)p_i \notin \text{supp}(G) and nNn\in\mathbb{N}. Although these codes are significant, their formal development for arbitrary genus remains incomplete in the literature, as most studies have concentrated on the genus 00 case. We present a rigorous treatment of this class of codes. Starting with a smooth projective curve XX, an invertible sheaf LL, and an effective divisor D=nipiD=\sum n_i p_i where the nin_i are not necessarily equal, as well as tuples of uniformizers tDt_D at the points of DD and trivializations γD\gamma_D for the localizations LpiL_{p_i}, the associated differential Goppa code is defined. This code arises from the theory of nn-jets of invertible sheaves on curves, which enables the description of codewords using Hasse-Schmidt derivatives of sections of LL. The variation of the code under changes in the data (tD,γD)(t_D, \gamma_D) is examined, and the group acting on these parameters is described. The behavior of the minimum Hamming distance under such variations is analyzed, with explicit examples provided for curves of genus 00 and 11. A duality theorem is established, involving principal parts of meromorphic differential forms. It is demonstrated that Goppa codes constitute a proper subclass of differential Goppa codes, and that every linear code admits a differential Goppa code structure on P1\mathbb P^1 using only two rational points.

Keywords

Cite

@article{arxiv.2603.04049,
  title  = {Differential Goppa Codes},
  author = {David González González and Ángel Luis Muñoz Castañeda and Luis Manuel Navas Vicente},
  journal= {arXiv preprint arXiv:2603.04049},
  year   = {2026}
}

Comments

43 pages, 0 figures

R2 v1 2026-07-01T11:02:59.977Z