Schr\"odingerization based quantum algorithms for the fractional Poisson equation
Abstract
We develop a quantum algorithm for solving high-dimensional fractional Poisson equations. By applying the Caffarelli-Silvestre extension, the -dimensional fractional equation is reformulated as a local partial differential equation in dimensions. We propose a quantum algorithm for the finite element discretization of this local problem, by capturing the steady-state of the corresponding differential equations using the Schr\"odingerization approach from \cite{JLY22SchrShort, JLY22SchrLong, analogPDE}. The Schr\"odingerization technique transforms general linear partial and ordinary differential equations into Schr\"odinger-type systems, making them suitable for quantum simulation. This is achieved through the warped phase transformation, which maps the equation into a higher-dimensional space. We provide detailed implementations of the method and conduct a comprehensive complexity analysis, which can show up to exponential advantage -- with respect to the inverse of the mesh size in high dimensions -- compared to its classical counterpart. Specifically, while the classical method requires operations, the quantum counterpart requires queries to the block-encoding input models, with the quantum complexity being independent of the dimension in terms of the inverse mesh size . Numerical experiments are conducted to verify the validity of our formulation.
Cite
@article{arxiv.2505.01602,
title = {Schr\"odingerization based quantum algorithms for the fractional Poisson equation},
author = {Shi Jin and Nana Liu and Yue Yu},
journal= {arXiv preprint arXiv:2505.01602},
year = {2025}
}
Comments
quantum algorithms for fractional differential equations