English

Sets of subspaces with restricted hyperplane intersection numbers

Combinatorics 2026-03-31 v1

Abstract

Let X\mathcal{X} be a set of (h1)(h-1)-dimensional subspaces of PG(kh1,q)\mathrm{PG}(kh-1,q) with the property that every hyperplane contains at most tt elements of X\mathcal{X}. We prove the upper bound X(tk+2)qh+t|\mathcal{X}| \leq (t-k+2)q^h + t, and characterise the structure of X\mathcal{X} in the case of equality. We call sets attaining this bound \emph{length-maximal}. For k=3k=3, such sets are known as maximal arcs and have been well-studied. They are known to exist for t<qht<q^h if and only if qq is even and tt divides qhq^h. For k=4k=4 and q>2q>2, we show that any length-maximal set must satisfy t=qh+1t = q^h+1 and that every hyperplane is either a tt-secant or a 11-secant. For k5k \geq 5 and q>2q>2, no length-maximal set exists. In the language of additive codes, these results assert that additive two-weight codes over Fqh\mathbb{F}_{q^h} attaining the natural Griesmer-type bound do not exist when the code dimension is 55 or more and q>2q>2.

Keywords

Cite

@article{arxiv.2603.27689,
  title  = {Sets of subspaces with restricted hyperplane intersection numbers},
  author = {Tim Alderson and Simeon Ball},
  journal= {arXiv preprint arXiv:2603.27689},
  year   = {2026}
}

Comments

9 pages

R2 v1 2026-07-01T11:42:53.646Z