MWS and FWS codes for coordinate-wise weight functions

IF 0.6 4区工程技术 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Applicable Algebra in Engineering Communication and Computing Pub Date : 2023-05-19 DOI:10.1007/s00200-023-00608-4

Tim Alderson, Benjamin Morine

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Abstract

A combinatorial problem concerning the maximum size of the (Hamming) weight set of an $$[n,k]_q$$ linear code was recently introduced. Codes attaining the established upper bound are the Maximum Weight Spectrum (MWS) codes. Those $$[n,k]_q$$ codes with the same weight set as $$\mathbb {F}_q^n$$ are called Full Weight Spectrum (FWS) codes. FWS codes are necessarily “short”, whereas MWS codes are necessarily “long”. For fixed k, q the values of n for which an $$[n,k]_q$$ -FWS code exists are completely determined, but the determination of the minimum length M(H, k, q) of an $$[n,k]_q$$ -MWS code remains an open problem. The current work broadens discussion first to general coordinate-wise weight functions, and then specifically to the Lee weight and a Manhattan like weight. In the general case we provide bounds on n for which an FWS code exists, and bounds on n for which an MWS code exists. When specializing to the Lee or to the Manhattan setting we are able to completely determine the parameters of FWS codes. As with the Hamming case, we are able to provide an upper bound on $$M({\mathscr {L}},k,q)$$ (the minimum length of Lee MWS codes), and pose the determination of $$M({\mathscr {L}},k,q)$$ as an open problem. On the other hand, with respect to the Manhattan weight we completely determine the parameters of MWS codes.

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坐标加权函数的MWS和FWS代码

最近介绍了一个关于$$[n,k]_q$$线性代码的(汉明)权集的最大尺寸的组合问题。达到设定上界的码是最大权谱(MWS)码。那些与$$\mathbb {F}_q^n$$具有相同权重设置的$$[n,k]_q$$代码称为全权重谱(FWS)代码。FWS代码必须是“短”的，而MWS代码必须是“长”的。对于固定的k, q可以完全确定$$[n,k]_q$$ -FWS代码存在的n值，但是确定$$[n,k]_q$$ -MWS代码的最小长度M(H, k, q)仍然是一个悬而未决的问题。目前的工作首先将讨论扩展到一般的坐标加权函数，然后具体到Lee权重和类似Manhattan的权重。在一般情况下，我们提供了n上存在一个FWS码的界，以及n上存在一个MWS码的界。当专门研究李或曼哈顿设置时，我们能够完全确定FWS代码的参数。与Hamming情况一样，我们能够提供$$M({\mathscr {L}},k,q)$$ (Lee MWS码的最小长度)的上界，并将$$M({\mathscr {L}},k,q)$$的确定作为一个开放问题。另一方面，相对于曼哈顿权重，我们完全确定了MWS代码的参数。

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

Applicable Algebra in Engineering Communication and Computing 工程技术-计算机：跨学科应用

CiteScore

2.90

自引率

14.30%

发文量

审稿时长

>12 weeks

期刊介绍： Algebra is a common language for many scientific domains. In developing this language mathematicians prove theorems and design methods which demonstrate the applicability of algebra. Using this language scientists in many fields find algebra indispensable to create methods, techniques and tools to solve their specific problems. Applicable Algebra in Engineering, Communication and Computing will publish mathematically rigorous, original research papers reporting on algebraic methods and techniques relevant to all domains concerned with computers, intelligent systems and communications. Its scope includes, but is not limited to, vision, robotics, system design, fault tolerance and dependability of systems, VLSI technology, signal processing, signal theory, coding, error control techniques, cryptography, protocol specification, networks, software engineering, arithmetics, algorithms, complexity, computer algebra, programming languages, logic and functional programming, algebraic specification, term rewriting systems, theorem proving, graphics, modeling, knowledge engineering, expert systems, and artificial intelligence methodology. Purely theoretical papers will not primarily be sought, but papers dealing with problems in such domains as commutative or non-commutative algebra, group theory, field theory, or real algebraic geometry, which are of interest for applications in the above mentioned fields are relevant for this journal. On the practical side, technology and know-how transfer papers from engineering which either stimulate or illustrate research in applicable algebra are within the scope of the journal.