English

Randomised algebraic constructions for the no-$(k+1)$-in-line problem

Combinatorics 2025-08-12 v1

Abstract

The no-(k+1)-in line problem seeks the maximum number of points that can be selected from an n×nn \times n square lattice such that no k+1k+1 of them are collinear. The problem was first posed more than 100100 years ago for the special case k=2k=2 and has remained open ever since. The general problem was recently resolved in the case kk is not small compared to nn, as Kov\'acs, Nagy and Szab\'o proved that the upper bound knkn can be attained, provided that k>Cnlognk>C\sqrt{n\log{n}} for an absolute constant CC. In this paper, we show that (12k)knfk(n)kn\left(1-\tfrac{2}{k}\right)kn \leq f_k(n)\leq kn and (13k)knfk(n)kn\left(1-\tfrac{3}{k}\right)kn \leq f_k(n)\leq kn hold for every even kk and odd kk, respectively, provided that nn is large enough. This is asymptotically tight as kk\to \infty. Previously, only fk(n)=Ω(kn)f_k(n)=\Omega(kn) was known due to Lefmann. We present further improvements on the lower bounds for constant values of kk when k<23k<23 holds. All these bounds are based on randomised algebraic constructions.

Keywords

Cite

@article{arxiv.2508.07632,
  title  = {Randomised algebraic constructions for the no-$(k+1)$-in-line problem},
  author = {Benedek Kovács and Zoltán Lóránt Nagy and Dávid R. Szabó},
  journal= {arXiv preprint arXiv:2508.07632},
  year   = {2025}
}

Comments

18 pages+Appendix (8 pages). Comments are welcome!

R2 v1 2026-07-01T04:43:39.499Z