The VC-dimension and point configurations in Fq2

Abstract

Let X be a set and H a collection of functions from X to \0,1\. We say that H shatters a finite set C ⊂ X if the restriction of H yields every possible function from C to \0,1\. The VC-dimension of H is the largest number d such that there exists a set of size d shattered by H, and no set of size d+1 is shattered by H. Vapnik and Chervonenkis introduced this idea in the early 70s in the context of learning theory, and this idea has also had a significant impact on other areas of mathematics. In this paper we study the VC-dimension of a class of functions H defined on Fqd, the d-dimensional vector space over the finite field with q elements. Define Hdt=\hy(x): y ∈ Fqd \, where for x ∈ Fqd, hy(x)=1 if ||x-y||=t, and 0 otherwise, where here, and throughout, ||x||=x12+x22+…+xd2. Here t ∈ Fq, t =0. Define Htd(E) the same way with respect to E ⊂ Fqd. The learning task here is to find a sphere of radius t centered at some point y ∈ E unknown to the learner. The learning process consists of taking random samples of elements of E of sufficiently large size. We are going to prove that when d=2, and |E| Cq158, the VC-dimension of H2t(E) is equal to 3. This leads to an intricate configuration problem which is interesting in its own right and requires a new approach.