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Parameter-Minimal Neural DE Solvers via Horner Polynomials

Machine Learning 2026-02-17 v1 Signal Processing

Abstract

We propose a parameter-minimal neural architecture for solving differential equations by restricting the hypothesis class to Horner-factorized polynomials, yielding an implicit, differentiable trial solution with only a small set of learnable coefficients. Initial conditions are enforced exactly by construction by fixing the low-order polynomial degrees of freedom, so training focuses solely on matching the differential-equation residual at collocation points. To reduce approximation error without abandoning the low-parameter regime, we introduce a piecewise ("spline-like") extension that trains multiple small Horner models on subintervals while enforcing continuity (and first-derivative continuity) at segment boundaries. On illustrative ODE benchmarks and a heat-equation example, Horner networks with tens (or fewer) parameters accurately match the solution and its derivatives and outperform small MLP and sinusoidal-representation baselines under the same training settings, demonstrating a practical accuracy-parameter trade-off for resource-efficient scientific modeling.

Keywords

Cite

@article{arxiv.2602.14737,
  title  = {Parameter-Minimal Neural DE Solvers via Horner Polynomials},
  author = {T. Matulić and D. Seršić},
  journal= {arXiv preprint arXiv:2602.14737},
  year   = {2026}
}

Comments

16 pages

R2 v1 2026-07-01T10:38:29.454Z