On upper bounds on the smallest size of a saturating set in a projective plane

Abstract

In a projective plane q (not necessarily Desarguesian) of order q, a point subset S is saturating (or dense) if any point of q S is collinear with two points in~S. Using probabilistic methods, the following upper bound on the smallest size s(2,q) of a saturating set in q is proved: equation* s(2,q)≤ 2(q+1) (q+1)+2 2q q. equation* We also show that for any constant c 1 a random point set of size k in q with 2c(q+1)(q+1)+2 k<q2-1q+2 q is a saturating set with probability greater than 1-1/(q+1)2c2-2. Our probabilistic approach is also applied to multiple saturating sets. A point set S⊂ q is (1,μ)-saturating if for every point Q of q S the number of secants of S through Q is at least μ , counted with multiplicity. The multiplicity of a secant is computed as \#( \, S)2. The following upper bound on the smallest size sμ (2,q) of a (1,μ)-saturating set in q is proved: equation* sμ (2,q)≤ 2(μ +1)(q+1) (q+1)+2 2(μ +1) q q\, for \,2≤ μ ≤ q. equation* By using inductive constructions, upper bounds on the smallest size of a saturating set (as well as on a (1,μ)-saturating set) in the projective space PG(N,q) are obtained. All the results are also stated in terms of linear covering codes.