Quantum preconditioning method for finite difference discretizations of the Poisson equation via Schrödingerization

Abstract

We present a quantum preconditioning framework for solving linear systems arising from a finite difference discretization of the Poisson equation. It is based on the combination of the Schrödingerization technique JLY22b,JLYPRL24 and the BPX multilevel preconditioner in order to achieve near-optimal complexity. The Schrödingerization technique transforms linear partial and ordinary differential equations into Schrödinger-type systems with unitary evolution in one higher dimension, making them suitable for quantum simulation. A key contribution is a structure-aware construction of the block-encoding for the symmetrically preconditioned matrix AS = S A S, where A is the stiffness matrix and S encodes the BPX preconditioner in factored form. By establishing a novel commuting identity, we avoid the unfavorable normalization scaling that would otherwise arise from naive multiplication of block-encodings. This yields an exact block-encoding of AS with normalization O(d2(L+1)), where d is the spatial dimension and L is the number of levels. Combined with the Schrödingerization-based Hamiltonian simulation, the overall quantum algorithm achieves a query complexity of O(poly(d)-1 polylog(-1) ) for estimating linear functionals of the solution to a given tolerance .