Optimal $$(2,\delta )$$ locally repairable codes via punctured simplex codes

IF 1.4 2区数学 Q3 COMPUTER SCIENCE, THEORY & METHODS Designs, Codes and Cryptography Pub Date : 2024-08-12 DOI:10.1007/s10623-024-01470-2

Yuan Gao, Weijun Fang, Jingke Xu, Dong Wang, Sihuang Hu

引用次数: 0

Abstract

Locally repairable codes (LRCs) have attracted a lot of attention due to their applications in distributed storage systems. In this paper, we provide new constructions of optimal $(2, \delta )$-LRCs over $\mathbb {F}_q$ with flexible parameters. Firstly, employing techniques from finite geometry, we introduce a simple yet useful condition to ensure that a punctured simplex code becomes a $(2, \delta )$-LRC. It is worth noting that this condition only imposes a requirement on the size of the puncturing set. Secondly, utilizing character sums over finite fields and Krawtchouk polynomials, we determine the parameters of more punctured simplex codes with puncturing sets of new structures. Several infinite families of LRCs with new parameters are derived. All of our new LRCs are optimal with respect to the generalized Cadambe–Mazumdar bound and some of them are also Griesmer codes or distance-optimal codes.

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通过穿刺单纯形码实现最优 $$(2,\delta )$$ 本地可修复码

局部可修复代码（LRC）因其在分布式存储系统中的应用而备受关注。在本文中，我们提供了具有灵活参数的最优$(2, \delta )$-LRCs的新构造。首先，利用有限几何的技术，我们引入了一个简单而有用的条件，以确保一个点状简并码成为一个（(2, \delta）-LRC。值得注意的是，这个条件只对穿刺集的大小提出了要求。其次，我们利用有限域上的特征和以及 Krawtchouk 多项式，确定了具有新结构的穿刺集的更多穿刺简并码的参数。我们推导出了几个具有新参数的无穷序列 LRC。我们的所有新 LRC 都是广义卡当贝-马祖姆达尔约束的最优码，其中一些还是格里斯梅尔码或距离最优码。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Designs, Codes and Cryptography 工程技术-计算机：理论方法

CiteScore

2.80

自引率

12.50%

发文量

157

审稿时长

16.5 months

期刊介绍： Designs, Codes and Cryptography is an archival peer-reviewed technical journal publishing original research papers in the designated areas. There is a great deal of activity in design theory, coding theory and cryptography, including a substantial amount of research which brings together more than one of the subjects. While many journals exist for each of the individual areas, few encourage the interaction of the disciplines. The journal was founded to meet the needs of mathematicians, engineers and computer scientists working in these areas, whose interests extend beyond the bounds of any one of the individual disciplines. The journal provides a forum for high quality research in its three areas, with papers touching more than one of the areas especially welcome. The journal also considers high quality submissions in the closely related areas of finite fields and finite geometries, which provide important tools for both the construction and the actual application of designs, codes and cryptographic systems. In particular, it includes (mostly theoretical) papers on computational aspects of finite fields. It also considers topics in sequence design, which frequently admit equivalent formulations in the journal’s main areas. Designs, Codes and Cryptography is mathematically oriented, emphasizing the algebraic and geometric aspects of the areas it covers. The journal considers high quality papers of both a theoretical and a practical nature, provided they contain a substantial amount of mathematics.