English

Quantum differential equation solvers: limitations and fast-forwarding

Quantum Physics 2025-07-10 v3 Numerical Analysis Numerical Analysis

Abstract

We study the limitations and fast-forwarding of quantum algorithms for linear ordinary differential equation (ODE) systems with a particular focus on non-quantum dynamics, where the coefficient matrix in the ODE is not anti-Hermitian or the ODE is inhomogeneous. On the one hand, for generic linear ODEs, by proving worst-case lower bounds, we show that quantum algorithms suffer from computational overheads due to two types of ``non-quantumness'': real part gap and non-normality of the coefficient matrix. We then show that homogeneous ODEs in the absence of both types of ``non-quantumness'' are equivalent to quantum dynamics, and reach the conclusion that quantum algorithms for quantum dynamics work best. To obtain these lower bounds, we propose a general framework for proving lower bounds on quantum algorithms that are amplifiers, meaning that they amplify the difference between a pair of input quantum states. On the other hand, we show how to fast-forward quantum algorithms for solving special classes of ODEs which leads to improved efficiency. More specifically, we obtain exponential improvements in both TT and the spectral norm of the coefficient matrix for inhomogeneous ODEs with efficiently implementable eigensystems, including various spatially discretized linear evolutionary partial differential equations. We give fast-forwarding algorithms that are conceptually different from existing ones in the sense that they neither require time discretization nor solving high-dimensional linear systems.

Keywords

Cite

@article{arxiv.2211.05246,
  title  = {Quantum differential equation solvers: limitations and fast-forwarding},
  author = {Dong An and Jin-Peng Liu and Daochen Wang and Qi Zhao},
  journal= {arXiv preprint arXiv:2211.05246},
  year   = {2025}
}

Comments

Published version with improved presentation

R2 v1 2026-06-28T05:33:33.825Z