Randomized Complexity of Parametric Integration and the Role of Adaption II. Sobolev Spaces

Abstract

We study the complexity of randomized computation of integrals depending on a parameter, with integrands from Sobolev spaces. That is, for r,d1,d2∈ N, 1 p,q ∞, D1= [0,1]d1, and D2= [0,1]d2 we are given f∈ Wpr(D1× D2) and we seek to approximate Sf=∫D2f(s,t)dt (s∈ D1), with error measured in the Lq(D1)-norm. Our results extend previous work of Heinrich and Sindambiwe (J.\ Complexity, 15 (1999), 317--341) for p=q=∞ and Wiegand (Shaker Verlag, 2006) for 1 p=q<∞. Wiegand's analysis was carried out under the assumption that Wpr(D1× D2) is continuously embedded in C(D1× D2) (embedding condition). We also study the case that the embedding condition does not hold. For this purpose a new ingredient is developed -- a stochastic discretization technique. The paper is based on Part I, where vector valued mean computation -- the finite-dimensional counterpart of parametric integration -- was studied. In Part I a basic problem of Information-Based Complexity on the power of adaption for linear problems in the randomized setting was solved. Here a further aspect of this problem is settled.