English

Arcs in $\mathbb F_q^2$

Combinatorics 2020-10-13 v2

Abstract

An arc is a subset of Fq2\mathbb F_q^2 which does not contain any collinear triples. Let A(q,k)A(q,k) denote the number of arcs in Fq2\mathbb F_q^2 with cardinality kk. This paper is primarily concerned with estimating the size of A(q,k)A(q,k) when kk is relatively large, namely k=qtk=q^t for some t>0t>0. Trivial estimates tell us that (qk)A(q,k)(q2k). {q \choose k} \leq A(q,k) \leq {q^2 \choose k}. We show that the behaviour of A(q,k)A(q,k) changes significantly close to t=1/2t=1/2. Below this threshold an elementary argument is used to prove that the trivial upper bound above cannot be improved significantly. On the other hand, for t1/2+δt \geq 1/2+\delta, we use the theory of hypergraph containers to get an improved upper bound A(q,k)(q2t+2δk). A(q,k) \leq {q^{2-t+2\delta} \choose k}. This technique is also used to give an upper bound for the size of the largest arc in a random subset of Fq2\mathbb F_q^2 which holds with high probability. For example, we prove that a pp-random subset QFq2Q \subset \mathbb F_q^2 with q3/2<p<q1q^{-3/2}<p<q^{-1} contains an arc of size Ω(q1/2)\Omega(q^{1/2}) with high probability. The result is optimal for this range of pp. Finally, this optimal bound for arcs in random sets is used to prove a finite field analogue of a result of Balogh and Solymosi, with a better exponent: there exists a subset PFq2P \subset \mathbb F_q^2 which does not contain any collinear quadruples, but with the property that for every PPP' \subset P with PP3/4+o(1)|P'| \geq |P|^{3/4+o(1)}, PP' contains a collinear triple.

Keywords

Cite

@article{arxiv.2003.03656,
  title  = {Arcs in $\mathbb F_q^2$},
  author = {Oliver Roche-Newton and Audie Warren},
  journal= {arXiv preprint arXiv:2003.03656},
  year   = {2020}
}

Comments

Several changes have been made for this version of the paper. The main difference is that the techniques are now also used to study the question of finding large arcs in random point sets. Theorem 3 presents an optimal result for this problem. Theorem 6 is also new. We have changed the title to reflect the broader focus of the paper

R2 v1 2026-06-23T14:07:37.436Z