English

Linear representations of subgeometries

Combinatorics 2014-07-16 v1

Abstract

The linear representation Tn(K)T_n^*(\mathcal{K}) of a point set K\mathcal{K} in a hyperplane of PG(n+1,q)\mathrm{PG}(n+1,q) is a point-line geometry embedded in this projective space. In this paper, we will determine the isomorphisms between two linear representations Tn(K)T_n^*(\mathcal{K}) and Tn(K)T_n^*(\mathcal{K}'), under a few conditions on K\mathcal{K} and K\mathcal{K}'. First, we prove that an isomorphism between Tn(K)T_n^*(\mathcal{K}) and Tn(K)T_n^*(\mathcal{K}') is induced by an isomorphism between the two linear representations Tn(K)T_n^*(\overline{\mathcal{K}}) and Tn(K)T_n^*(\overline{\mathcal{K}'}) of their closures K\overline {\mathcal{K}} and K\overline{\mathcal{K}'}. This allows us to focus on the automorphism group of a linear representation Tn(S)T_n^*(\mathcal{S}) of a subgeometry SPG(n,q)\mathcal{S}\cong\mathrm{PG}(n,q) embedded in a hyperplane of the projective space PG(n+1,qt)\mathrm{PG}(n+1,q^t). To this end we introduce a geometry X(n,t,q)X(n,t,q) and determine its automorphism group. The geometry X(n,t,q)X(n,t,q) is a straightforward generalization of Hqn+2H_{q}^{n+2} which is known to be isomorphic to the linear representation of a Baer subgeometry. By providing an elegant algebraic description of X(n,t,q)X(n,t,q) as a coset geometry we extend this result and prove that X(n,t,q)X(n,t,q) and Tn(S)T_n^*(\mathcal{S}) are isomorphic. Finally, we compare the full automorphism group of Tn(S)T^*_n(\mathcal{S}) with the "natural" group of automorphisms that is induced by the collineation group of its ambient space.

Keywords

Cite

@article{arxiv.1407.3953,
  title  = {Linear representations of subgeometries},
  author = {Stefaan De Winter and Sara Rottey and Geertrui Van de Voorde},
  journal= {arXiv preprint arXiv:1407.3953},
  year   = {2014}
}
R2 v1 2026-06-22T05:04:22.815Z