Optimal pointwise sampling for L2 approximation

Abstract

Given a function u∈ L2=L2(D,μ), where D⊂ Rd and μ is a measure on D, and a linear subspace Vn⊂ L2 of dimension n, we show that near-best approximation of u in Vn can be computed from a near-optimal budget of Cn pointwise evaluations of u, with C>1 a universal constant. The sampling points are drawn according to some random distribution, the approximation is computed by a weighted least-squares method, and the error is assessed in expected L2 norm. This result improves on the results in [6,8] which require a sampling budget that is sub-optimal by a logarithmic factor, thanks to a sparsification strategy introduced in [17,18]. As a consequence, we obtain for any compact class K⊂ L2 that the sampling number Cn rand( K)L2 in the randomized setting is dominated by the Kolmogorov n-width dn( K)L2. While our result shows the existence of a randomized sampling with such near-optimal properties, we discuss remaining issues concerning its generation by a computationally efficient algorithm.