{"title":"有限域上多项式的相交族","authors":"Nika Salia , Dávid Tóth","doi":"10.1016/j.ffa.2024.102540","DOIUrl":null,"url":null,"abstract":"<div><div>This paper demonstrates an analog of the Erdős–Ko–Rado theorem to polynomial rings over finite fields, affirmatively answering a conjecture of C. Tompkins.</div><div>A <em>k</em>-uniform family of subsets of a set of size <em>n</em> is <em>ℓ</em>-intersecting if any two subsets in the family intersect in at least <em>ℓ</em> elements. The study of such intersecting families is a core subject of extremal set theory, tracing its roots to the seminal 1961 Erdős–Ko–Rado theorem, which establishes a sharp upper bound on the size of these families. 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Tompkins.</div><div>A <em>k</em>-uniform family of subsets of a set of size <em>n</em> is <em>ℓ</em>-intersecting if any two subsets in the family intersect in at least <em>ℓ</em> elements. The study of such intersecting families is a core subject of extremal set theory, tracing its roots to the seminal 1961 Erdős–Ko–Rado theorem, which establishes a sharp upper bound on the size of these families. Here, we extend the Erdős–Ko–Rado theorem to polynomial rings over finite fields.</div><div>Specifically, we determine the largest possible size of a family of monic polynomials, each of degree <em>n</em>, over a finite field <span><math><msub><mrow><mi>F</mi></mrow><mrow><mi>q</mi></mrow></msub></math></span>, where every pair of polynomials in the family shares a common factor of degree at least <em>ℓ</em>. 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引用次数: 0
摘要
本文证明了厄尔多-柯-拉多定理在有限域上多项式环中的类比,肯定地回答了汤普金斯(C. Tompkins)的猜想。如果一个大小为 n 的集合的 k 个均匀子集族中的任意两个子集至少有 ℓ 个元素相交,那么这个子集族就是 ℓ 相交族。对这种相交族的研究是极值集合理论的核心课题,其根源可追溯到 1961 年的开创性厄多-柯-拉多定理,该定理为这些族的大小确定了一个尖锐的上限。在这里,我们将厄尔多斯-柯-拉多定理扩展到有限域上的多项式环。具体地说,我们确定了有限域 Fq 上每个度数为 n 的单项式族的最大可能规模,其中族中的每对多项式都有一个度数至少为 ℓ 的公因子。我们证明了这一大小的上界是 qn-ℓ,并描述了达到这一最大大小的所有极值族的特征。扩展到三重相交族,其中每个三重多项式共享至少 ℓ 阶的公因子,我们证明只有三重族达到了相应的上界。此外,通过将条件放宽到包括阶数至多为 n 的多项式,我们肯定只有三交系达到了相应的上限。
Intersecting families of polynomials over finite fields
This paper demonstrates an analog of the Erdős–Ko–Rado theorem to polynomial rings over finite fields, affirmatively answering a conjecture of C. Tompkins.
A k-uniform family of subsets of a set of size n is ℓ-intersecting if any two subsets in the family intersect in at least ℓ elements. The study of such intersecting families is a core subject of extremal set theory, tracing its roots to the seminal 1961 Erdős–Ko–Rado theorem, which establishes a sharp upper bound on the size of these families. Here, we extend the Erdős–Ko–Rado theorem to polynomial rings over finite fields.
Specifically, we determine the largest possible size of a family of monic polynomials, each of degree n, over a finite field , where every pair of polynomials in the family shares a common factor of degree at least ℓ. We prove that the upper bound for this size is and characterize all extremal families that achieve this maximum size.
Extending to triple-intersecting families, where every triplet of polynomials shares a common factor of degree at least ℓ, we prove that only trivial families achieve the corresponding upper bound. Moreover, by relaxing the conditions to include polynomials of degree at most n, we affirm that only trivial families achieve the corresponding upper bound.
期刊介绍:
Finite Fields and Their Applications is a peer-reviewed technical journal publishing papers in finite field theory as well as in applications of finite fields. As a result of applications in a wide variety of areas, finite fields are increasingly important in several areas of mathematics, including linear and abstract algebra, number theory and algebraic geometry, as well as in computer science, statistics, information theory, and engineering.
For cohesion, and because so many applications rely on various theoretical properties of finite fields, it is essential that there be a core of high-quality papers on theoretical aspects. In addition, since much of the vitality of the area comes from computational problems, the journal publishes papers on computational aspects of finite fields as well as on algorithms and complexity of finite field-related methods.
The journal also publishes papers in various applications including, but not limited to, algebraic coding theory, cryptology, combinatorial design theory, pseudorandom number generation, and linear recurring sequences. There are other areas of application to be included, but the important point is that finite fields play a nontrivial role in the theory, application, or algorithm.
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