English

Data Assimilation and Sampling in Banach spaces

Numerical Analysis 2016-08-08 v3

Abstract

This paper studies the problem of approximating a function ff in a Banach space XX from measurements lj(f)l_j(f), j=1,,mj=1,\dots,m, where the ljl_j are linear functionals from XX^*. Most results study this problem for classical Banach spaces XX such as the LpL_p spaces, 1p1\le p\le \infty, and for KK the unit ball of a smoothness space in XX. Our interest in this paper is in the model classes K=K(ϵ,V)K=K(\epsilon,V), with ϵ>0\epsilon>0 and VV a finite dimensional subspace of XX, which consists of all fXf\in X such that dist(f,V)Xϵdist(f,V)_X\le \epsilon. These model classes, called {\it approximation sets}, arise naturally in application domains such as parametric partial differential equations, uncertainty quantification, and signal processing. A general theory for the recovery of approximation sets in a Banach space is given. This theory includes tight a priori bounds on optimal performance, and algorithms for finding near optimal approximations. We show how the recovery problem for approximation sets is connected with well-studied concepts in Banach space theory such as liftings and the angle between spaces. Examples are given that show how this theory can be used to recover several recent results on sampling and data assimilation.

Keywords

Cite

@article{arxiv.1602.06342,
  title  = {Data Assimilation and Sampling in Banach spaces},
  author = {Ronald DeVore and Guergana Petrova and Przemyslaw Wojtaszczyk},
  journal= {arXiv preprint arXiv:1602.06342},
  year   = {2016}
}
R2 v1 2026-06-22T12:54:09.528Z