English

A Note on Non-Negative $L_1$-Approximating Polynomials

Machine Learning 2026-05-11 v1 Data Structures and Algorithms Machine Learning Statistics Theory Statistics Theory

Abstract

L1L_1-Approximating polynomials, i.e., polynomials that approximate indicator functions in L1L_1-norm under certain distributions, are widely used in computational learning theory. We study the existence of \textit{non-negative} L1L_1-approximating polynomials with respect to Gaussian distributions. This is a stronger requirement than L1L_1-approximation but weaker than sandwiching polynomials (which themselves have many applications). These non-negative approximating polynomials have recently found uses in smoothed learning from positive-only examples. In this short note, we prove that every class of sets with Gaussian surface area (GSA) at most Γ\Gamma under the standard Gaussian admits degree-kk non-negative polynomials that \eps\eps-approximate its indicator functions in L1L_1-norm, for k=O~(Γ2/ε2)k=\tilde{O}(\Gamma^2/\varepsilon^2). Equivalently, finite GSA implies L1L_1-approximation with the stronger pointwise guarantee that the approximating polynomial has range contained in [0,)[0,\infty). Up to a constant-factor, this matches the degree of the best currently known Gaussian L1L_1-approximation degree bound without the non-negativity constraint.

Cite

@article{arxiv.2605.08072,
  title  = {A Note on Non-Negative $L_1$-Approximating Polynomials},
  author = {Jane H. Lee and Anay Mehrotra and Manolis Zampetakis},
  journal= {arXiv preprint arXiv:2605.08072},
  year   = {2026}
}
R2 v1 2026-07-01T12:58:18.836Z