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A quantum-inspired multi-level tensor-train monolithic space-time method for nonlinear PDEs

Numerical Analysis 2026-02-10 v1 Numerical Analysis Performance Computational Physics Quantum Physics

Abstract

We propose a multilevel tensor-train (TT) framework for solving nonlinear partial differential equations (PDEs) in a global space-time formulation. While space-time TT solvers have demonstrated significant potential for compressed high-dimensional simulations, the literature contains few systematic comparisons with classical time-stepping methods, limited error convergence analyses, and little quantitative assessment of the impact of TT rounding on numerical accuracy. Likewise, existing studies fail to demonstrate performance across a diverse set of PDEs and parameter ranges. In practice, monolithic Newton iterations may stagnate or fail to converge in strongly nonlinear, stiff, or advection-dominated regimes, where poor initial guesses and severely ill-conditioned space-time Jacobians hinder robust convergence. We overcome this limitation by introducing a coarse-to-fine multilevel strategy fully embedded within the TT format. Each level refines both spatial and temporal resolutions while transferring the TT solution through low-rank prolongation operators, providing robust initializations for successive Newton solves. Residuals, Jacobians, and transfer operators are represented directly in TT and solved with the adaptive-rank DMRG algorithm. Numerical experiments for a selection of nonlinear PDEs including Fisher-KPP, viscous Burgers, sine-Gordon, and KdV cover diffusive, convective, and dispersive dynamics, demonstrating that the multilevel TT approach consistently converges where single-level space-time Newton iterations fail. In dynamic, advection-dominated (nonlinear) scenarios, multilevel TT surpasses single-level TT, achieving high accuracy with significantly reduced computational cost, specifically when high-fidelity numerical simulation is required.

Keywords

Cite

@article{arxiv.2602.07945,
  title  = {A quantum-inspired multi-level tensor-train monolithic space-time method for nonlinear PDEs},
  author = {N. R. Rapaka and R. Peddinti and E. Tiunov and N. J. Faraj and A. N. Alkhooori and L. Aolita and Y. Addad and M. K. Riahi},
  journal= {arXiv preprint arXiv:2602.07945},
  year   = {2026}
}

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R2 v1 2026-07-01T10:26:41.934Z