Covering half-grids with lines and planes

Abstract

We study hyperplane covering problems for finite grid-like structures in Rd. We call a set C of points in R2 a conical grid if the line y = ai intersects C in exactly i points, for some a1 > ·s > an ∈ R. We prove that the number of lines required to cover every point of such a grid at least k times is at least nk(1-1e-O(1n) ). If the grid C is obtained by cutting an m × n grid of points in half along one of the diagonals, then we prove the lower bound of mk(1-e-nm-O(nm2)). In general, we call a grid obtained by cutting a grid in Rd along one of the diagonals a half-grid. Motivated by the Alon-Füredi theorem on hyperplane coverings of grids that miss a point and its multiplicity variations, we study the problem of finding the minimum number of hyperplanes required to cover every point of an n × ·s × n half-grid in Rd at least k times while missing a point P. For almost all such half-grids, with P being the corner point, we prove asymptotically sharp upper and lower bounds for the covering number in dimensions 2 and 3. For k = 1, d = 2, and an arbitrary P, we determine this number exactly by using the polynomial method bound for grids.