English

Graphs from quadratic forms and vector spaces over finite fields

Combinatorics 2026-05-22 v1 Discrete Mathematics Number Theory

Abstract

Let qq be an odd prime power, let n2n\ge 2, and let VFqnV\subsetneq \mathbb F_{q^n} be a proper Fq\mathbb F_q-vector subspace. Given a nonzero quadratic form Q(X,Y)Fqn[X,Y]Q(X,Y)\in \mathbb F_{q^n}[X,Y], we consider the graph Γ(Q,V)\Gamma(Q,V) that naturally arises from the condition Q(X,Y)VQ(X,Y)\in V. We determine all quadratic forms QQ for which Γ(Q,V)\Gamma(Q,V) is undirected for every VV. Besides the case Q(x,y)=XYQ(x,y)=XY, studied earlier by the second author, this essentially leads to the forms X2±Y2X^2\pm Y^2 and the family Qb(X,Y):=X2+bXY+Y2,b0Q_b(X, Y):=X^2+bXY+Y^2, b\ne 0. We then study connectedness and clique number for the corresponding graphs. Our results reveal a clear contrast between these cases. The graphs Γ(X2±Y2,V)\Gamma(X^2\pm Y^2, V) are well structured, disconnected and their clique number can be as large as #V\# V. On the other hand, the family QbQ_b seems to yield less structured graphs: the graphs are connected (in fact, of diameter 22) if #Vq3n/4\# V\ge q^{3n/4} and, in many cases, their clique number is o(#V)o(\# V). Our proofs are mainly based on character sums, while requiring a few algebraic and combinatorial ideas. We end the paper with some open problems and remarks, including a short discussion of the complementary case where qq is even.

Keywords

Cite

@article{arxiv.2605.21866,
  title  = {Graphs from quadratic forms and vector spaces over finite fields},
  author = {Jean Godard and Lucas Reis},
  journal= {arXiv preprint arXiv:2605.21866},
  year   = {2026}
}

Comments

12 pages; comments are welcome!