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Stability of Least Squares Approximation under Random Sampling

Numerical Analysis 2026-02-17 v2 Numerical Analysis

Abstract

This paper investigates the stability of the least squares approximation PmnP_m^n within the univariate polynomial space of degree mm, denoted by Pm{\mathbb P}_m. The approximation PmnP_m^n entails identifying a polynomial in Pm{\mathbb P}_m that approximates a function ff over a domain XX based on samples of ff taken at nn randomly selected points, according to a specified probability measure ρX\rho_X. The primary goal is to determine the sampling rate necessary to ensure the stability of PmnP_m^n. Assuming the sampling points are i.i.d. with respect to a Jacobi weight function, we present the sampling rate that guarantee the stability of PmnP_m^n. Specifically, for uniform random sampling, we demonstrate that a sampling rate of nm2n \asymp m^2 is required to maintain stability. By combining these findings with those of Cohen-Davenport-Leviatan, we conclude that, for uniform random sampling, the optimal sampling rate for guaranteeing the stability of PmnP_m^n is nm2n \asymp m^2, up to a logn\log n factor. Motivated by this result, we extend the impossibility theorem, previously applicable to equally spaced samples, to the case of random samples, illustrating the balance between accuracy and stability in recovering analytic functions.

Keywords

Cite

@article{arxiv.2407.10221,
  title  = {Stability of Least Squares Approximation under Random Sampling},
  author = {Zhiqiang Xu and Xinyue Zhang},
  journal= {arXiv preprint arXiv:2407.10221},
  year   = {2026}
}
R2 v1 2026-06-28T17:40:20.867Z