No-(k+1)-in-line problem for k ≥slant 3

Abstract

What is the maximum number of points one can place in an n × n grid such that every Euclidean line contains at most k points? For k = 2, this is the notorious no-three-in-line problem of Dudeney. In this paper, we resolve this problem for all other k (and sufficiently large n). Namely, for k ≥slant 3 and sufficiently large n, we show that this maximum is exactly kn. To prove this, our key observation is that in the regime k ≥slant 3, the problem is dominated in a certain statistical sense by the influence of a small number of "heavy" lines with many grid points. We apply a result of Ehard-Glock-Joos on pseudorandom hypergraph matchings to construct a set of size kn - o(n) with at most k points on each heavy line, and then a crude deletion argument yields a no-(k+1)-in-line set of nearly the same size. Finally, we use a randomised switching procedure to complete the construction (building upon ideas of Simkin and Luria). Using similar ideas, we also address the no-four-on-a-circle problem of Erdős and Purdy. Namely, we prove the existence of a set of 2n - o(n) points in the n × n grid such that no four of these points lie on a circle or a line, improving on the previous construction of size n - o(n) due to Dong and Xu.

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