Quantum-Inspired Tensor Networks for Approximating PDE Flow Maps
Abstract
We investigate quantum-inspired tensor networks (QTNs) for approximating flow maps of hydrodynamic partial differential equations (PDEs). Motivated by the effective low-rank structure that emerges after tensorization of discretized transport and diffusion dynamics, we encode PDE states as matrix product states (MPS) and represent the evolution operator as a structured low-rank matrix product operator (MPO) in tensor-train form (e.g., arising from finite-difference discretizations assembled in MPO form). The MPO is applied directly in MPS form, and rank growth is controlled via canonicalization and SVD-based truncation after each step. We provide theoretical context through standard matrix product properties, including exact MPS representability bounds, local optimality of SVD truncation, and a Lipschitz-type multi-step error propagation estimate. Experiments on one- and two-dimensional linear advection-diffusion and nonlinear viscous Burgers equations demonstrate accurate short-horizon prediction, favorable scaling in smooth diffusive regimes, and error growth in nonlinear multi-step predictions.
Cite
@article{arxiv.2602.15906,
title = {Quantum-Inspired Tensor Networks for Approximating PDE Flow Maps},
author = {Nahid Binandeh Dehaghani and Ban Q. Tran and Rafal Wisniewski and Susan Mengel and A. Pedro Aguiar},
journal= {arXiv preprint arXiv:2602.15906},
year = {2026}
}
Comments
7 pages, 4 figures