English

Moment-based Piecewise Polynomial Probability Density Estimation with Quantile-Based Binning

General Mathematics 2026-03-03 v1

Abstract

Accurate reconstruction of probability density functions (PDFs) from data is essential in engineering applications. Classical global moment-based polynomial approximations often suffer from oscillations, instability in the tails, and sensitivity to the choice of support. This work proposes a quantile-based piecewise polynomial density reconstruction approach that combines equal-probability binning with local moment-matched polynomials within each bin. Two variants are considered: piecewise monomial and piecewise Lagrange polynomials with Chebyshev nodes. The numbers of bins and polynomial degrees are selected by a proposed grid search approach guided by the Kolmogorov-Smirnov (K-S) test statistic under non-negativity constraints. Across several benchmark distributions, the proposed methods reduce K-S errors by about 8080-96%96\% relative to standard monomial and Lagrange polynomial approaches, and by about 8383-97%97\% compared with spline density estimation. For real-world household electricity consumption and solar irradiance data, the piecewise approaches achieve K-S test statistic performance comparable to kernel density estimation while offering improved control over tail behavior and oscillations. Overall, the results demonstrate that quantile-based localization substantially enhances the robustness and fidelity of moment-based polynomial PDF reconstruction.

Keywords

Cite

@article{arxiv.2603.00209,
  title  = {Moment-based Piecewise Polynomial Probability Density Estimation with Quantile-Based Binning},
  author = {Meltem Turan and Joakim Munkhammar},
  journal= {arXiv preprint arXiv:2603.00209},
  year   = {2026}
}

Comments

40 pages, 8 figures

R2 v1 2026-07-01T10:56:26.966Z