Probability error bounds for approximation of functions in reproducing kernel Hilbert spaces

Abstract

We find probability error bounds for approximations of functions f in a separable reproducing kernel Hilbert space H with reproducing kernel K on a base space X, firstly in terms of finite linear combinations of functions of type Kxi and then in terms of the projection πnx on Span\Kxi\ni=1, for random sequences of points x=(xi)i in X. Given a probability measure P, letting PK be the measure defined by d PK(x)=K(x,x)d P(x), x∈ X, our approach is based on the nonexpansive operator \[L2(X;PK)λ LP,Kλ:=∫X λ(x)Kxd P(x)∈ H,\] where the integral exists in the Bochner sense. Using this operator, we then define a new reproducing kernel Hilbert space, denoted by HP, that is the operator range of LP,K. Our main result establishes bounds, in terms of the operator LP,K, on the probability that the Hilbert space distance between an arbitrary function f∈H and linear combinations of functions of type Kxi, for (xi)i sampled independently from P, falls below a given threshold. For sequences of points (xi)i=1∞ constituting a so-called uniqueness set, the orthogonal projections πnx to Span\Kxi\ni=1 converge in the strong operator topology to the identity operator. We prove that, under the assumption that HP is dense in H, any sequence of iid samples from P yields a uniqueness set with probability 1. This result improves on previous error bounds in weaker norms, such as uniform or Lp norms, which yield only convergence in probability and not a.c. convergence. Two examples that show the applicability of this result to a uniform distribution on a compact interval and to the Hardy space H2(D) are presented as well.