English

On the equational graphs over finite fields

Combinatorics 2020-03-09 v3 Number Theory

Abstract

In this paper, we generalize the notion of functional graph. Specifically, given an equation E(X,Y)=0E(X,Y) = 0 with variables XX and YY over a finite field Fq\mathbb{F}_q of odd characteristic, we define a digraph by choosing the elements in Fq\mathbb{F}_q as vertices and drawing an edge from xx to yy if and only if E(x,y)=0E(x,y)=0. We call this graph as equational graph. In this paper, we study the equational graphs when choosing E(X,Y)=(Y2f(X))(λY2f(X))E(X,Y) = (Y^2 - f(X))(\lambda Y^2 - f(X)) with f(X)f(X) a polynomial over Fq\mathbb{F}_q and λ\lambda a non-square element in Fq\mathbb{F}_q. We show that if ff is a permutation polynomial over Fq\mathbb{F}_q, then every connected component of the graph has a Hamiltonian cycle. Moreover, these Hamiltonian cycles can be used to construct balancing binary sequences. By making computations for permutation polynomials ff of low degree, it appears that almost all these graphs are strongly connected, and there are many Hamiltonian cycles in such a graph if it is connected.

Keywords

Cite

@article{arxiv.1906.12054,
  title  = {On the equational graphs over finite fields},
  author = {Bernard Mans and Min Sha and Jeffrey Smith and Daniel Sutantyo},
  journal= {arXiv preprint arXiv:1906.12054},
  year   = {2020}
}

Comments

32 pages. To appear in Finite Fields and Their Applications

R2 v1 2026-06-23T10:06:23.207Z