On the Wasserstein Distance between Classical Sequences and the Lebesgue Measure

Abstract

We discuss the classical problem of measuring the regularity of distribution of sets of N points in Td. A recent line of investigation is to study the cost (= mass × distance) necessary to move Dirac measures placed in these points to the uniform distribution. We show that Kronecker sequences satisfy optimal transport distance in d ≥ 3 dimensions. This shows that for differentiable f: Td → R and badly approximable vectors α ∈ Rd, we have \ | ∫Td f(x) dx - 1N Σk=1N f(k α) \ | ≤ cα \| ∇ f\|(d-1)/dL∞\| ∇ f\|1/dL2 N1/d. We note that the result is uniformly true for a sequence instead of a set. Simultaneously, it refines the classical integration error for Lipschitz functions, \| ∇ f\|L∞ N-1/d. We obtain a similar improvement for numerical integration with respect to the regular grid. The main ingredient is an estimate involving Fourier coefficients of a measure; this allows for existing estimates to be conviently `recycled'. We present several open problems.