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Milstein-type Schemes for Hyperbolic SPDEs

Numerical Analysis 2026-02-03 v3 Numerical Analysis Analysis of PDEs Functional Analysis Probability

Abstract

This article studies the temporal approximation of hyperbolic semilinear stochastic evolution equations with multiplicative Gaussian noise by Milstein-type schemes. We take the term hyperbolic to mean that the leading operator generates a contractive, not necessarily analytic C0C_0-semigroup. Optimal convergence rates are derived for the pathwise uniform strong error Eh:=(E[max1jMUtjujXp])1/p E_h^\infty := \Big(\mathbb{E}\Big[\max_{1\le j \le M}\|U_{t_j}-u_j\|_X^p\Big]\Big)^{1/p} on a Hilbert space XX for p[2,)p\in [2,\infty). Here, UU is the mild solution and uju_j its Milstein approximation at time tj=jht_j=jh with step size h>0h>0 and final time T=Mh>0T=Mh>0. For sufficiently regular nonlinearity and noise, we establish strong convergence of order one, with the error satisfying Ehhlog(T/h)E_h^\infty\lesssim h\sqrt{\log(T/h)} for rational Milstein schemes and EhhE_h^\infty \lesssim h for exponential Milstein schemes. This extends previous results from parabolic to hyperbolic SPDEs and from exponential to rational Milstein schemes. Moreover, root-mean-square error estimates are strengthened to pathwise uniform estimates. Numerical experiments validate the convergence rates for the stochastic Schr\"odinger equation. Further applications to Maxwell's and transport equations are included.

Keywords

Cite

@article{arxiv.2512.19647,
  title  = {Milstein-type Schemes for Hyperbolic SPDEs},
  author = {Felix Kastner and Katharina Klioba},
  journal= {arXiv preprint arXiv:2512.19647},
  year   = {2026}
}

Comments

39 pages, 1 figure, 3 tables. Minor corrections. Comments are welcome!

R2 v1 2026-07-01T08:37:21.766Z