On the approximation of vector-valued functions by volume sampling

Abstract

Given a Hilbert space H and a finite measure space , the approximation of a vector-valued function f: H by a k-dimensional subspace U ⊂ H plays an important role in dimension reduction techniques, such as reduced basis methods for solving parameter-dependent partial differential equations. For functions in the Lebesgue-Bochner space L2(; H), the best possible subspace approximation error dk(2) is characterized by the singular values of f. However, for practical reasons, U is often restricted to be spanned by point samples of f. We show that this restriction only has a mild impact on the attainable error; there always exist k samples such that the resulting error is not larger than k+1 · dk(2). Our work extends existing results by Binev at al. (SIAM J. Math. Anal., 43(3):1457-1472, 2011) on approximation in supremum norm and by Deshpande et al. (Theory Comput., 2:225-247, 2006) on column subset selection for matrices.