A characterization theorem for the L2-discrepancy of integer points in dilated polygons

Abstract

Let C be a convex d-dimensional body. If is a large positive number, then the dilated body C contains d C +O( d-1) integer points, where C denotes the volume of C. The above error estimate O( d-1) can be improved in several cases. We are interested in the L2-discrepancy DC() of a copy of C thrown at random in Rd. More precisely, we consider \[ DC():=\ ∫Td∫SO(d) card( ( σ(C)+t) d) - d C 2dσ dt\ 1/2\ , \] where Td= Rd/Zd is the d-dimensional flat torus and SO( d) is the special orthogonal group of real orthogonal matrices of determinant 1. An argument of D. Kendall shows that DC()≤ c\ (d-1)/2. If C also satisfies the reverse inequality \ DC()≥ c1 \ (d-1)/2, we say that C is L2-regular. L. Parnovski and A. Sobolev proved that, if d>1, a d-dimensional unit ball is L2% -regular if and only if d 1\ (mod4). In this paper we characterize the L2-regular convex polygons. More precisely we prove that a convex polygon is not L2-regular if and only if it can be inscribed in a circle and it is symmetric about the centre.