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Pseudospectral method for solving PDEs using Matrix Product States

Quantum Physics 2026-03-18 v2 Numerical Analysis Numerical Analysis

Abstract

This research focuses on solving time-dependent partial differential equations (PDEs), in particular the time-dependent Schr\"odinger equation, using matrix product states (MPS). We propose an extension of Hermite Distributed Approximating Functionals (HDAF) to MPS, a highly accurate pseudospectral method for approximating functions of derivatives. Integrating HDAF into an MPS finite precision algebra, we test four types of quantum-inspired algorithms for time evolution: explicit Runge-Kutta methods, Crank-Nicolson method, explicitly restarted Arnoli iteration and split-step. The benchmark problem is the expansion of a particle in a quantum quench, characterized by a rapid increase in space requirements, where HDAF surpasses traditional finite difference methods in accuracy with a comparable cost. Moreover, the efficient HDAF approximation to the free propagator avoids the need for Fourier transforms in split-step methods, significantly enhancing their performance with an improved balance in cost and accuracy. Both approaches exhibit similar error scaling and run times compared to FFT vector methods; however, MPS offer an exponential advantage in memory, overcoming vector limitations to enable larger discretizations and expansions. Finally, the MPS HDAF split-step method successfully reproduces the physical behavior of a particle expansion in a double-well potential, demonstrating viability for actual research scenarios.

Keywords

Cite

@article{arxiv.2409.02916,
  title  = {Pseudospectral method for solving PDEs using Matrix Product States},
  author = {Jorge Gidi and Paula García-Molina and Luca Tagliacozzo and Juan José García-Ripoll},
  journal= {arXiv preprint arXiv:2409.02916},
  year   = {2026}
}
R2 v1 2026-06-28T18:34:22.686Z