Polynomial-order oscillations in geometric discrepancy

Abstract

Let C⊂R2 be a convex body, and for a positive integer N, let P be a configuration of N points in [0,1)2. The discrepancy of P with respect to C is defined by equation* D(P,\, C)=Σp∈PΣn∈Z21C(p+n)-N|C|, equation* and one may estimate how P deviates from uniformity by averaging the latter quantity over a family of sets. When considering quadratic averages over translated and dilated copies of C, one gets the homothetic quadratic discrepancy equation* D2(P,\, C)=∫01∫[0,1)2|D( P,\,τ+δ C)|2\, dτ\, d δ. equation* We investigate the behaviour of the optimal homothetic quadratic discrepancy, that is equation* ∈f\# P=N D2(P,\, C) N+∞. equation* Beck~MR915529 and Beck and Chen~MR1489133 showed that the optimal h.q.d. of convex polygons has an order of growth of N, and more recently, Brandolini and Travaglini~MR4358540 proved that the optimal h.q.d. of planar convex bodies with a C2 boundary has an order of growth of N1/2. We show that, in general, a single order of growth for the optimal h.q.d. need not exist. First, by an implicit geometric construction of C, we obtain prescribed oscillations between N and N1/2. Second, by a subtler design of ∂ C and via Fourier-analytic methods, we obtain prescribed polynomial-order oscillations in the range Nα with α∈(2/5,1/2).