Multivariate approximation of functions on irregular domains by weighted least-squares methods

Abstract

We propose and analyse numerical algorithms based on weighted least squares for the approximation of a real-valued function on a general bounded domain ⊂ Rd. Given any n-dimensional approximation space Vn ⊂ L2(), the analysis in [6] shows the existence of stable and optimally converging weighted least-squares estimators, using a number of function evaluations m of the order n n. When an L2()-orthonormal basis of Vn is available in analytic form, such estimators can be constructed using the algorithms described in [6,Section 5]. If the basis also has product form, then these algorithms have computational complexity linear in d and m. In this paper we show that, when is an irregular domain such that the analytic form of an L2()-orthonormal basis is not available, stable and quasi-optimally weighted least-squares estimators can still be constructed from Vn, again with m of the order n n, but using a suitable surrogate basis of Vn orthonormal in a discrete sense. The computational cost for the calculation of the surrogate basis depends on the Christoffel function of and Vn. Numerical results validating our analysis are presented.