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Quantum Multi-Resolution Measurement with application to Quantum Linear Solver

Quantum Physics 2023-04-13 v1

Abstract

Quantum computation consists of a quantum state corresponding to a solution, and measurements with some observables. To obtain a solution with an accuracy ϵ\epsilon, measurements O(n/ϵ2)O(n/\epsilon^2) are required, where nn is the size of a problem. The cost of these measurements requires a large computing time for an accurate solution. In this paper, we propose a quantum multi-resolution measurement (QMRM), which is a hybrid quantum-classical algorithm that gives a solution with an accuracy ϵ\epsilon in O(nlog(1/ϵ))O(n\log(1/\epsilon)) measurements using a pair of functions. The QMRM computational cost with an accuracy ϵ\epsilon is smaller than O(n/ϵ2)O(n/\epsilon^2). We also propose an algorithm entitled QMRM-QLS (quantum linear solver) for solving a linear system of equations using the Harrow-Hassidim-Lloyd (HHL) algorithm as one of the examples. We perform some numerical experiments that QMRM gives solutions to with an accuracy ϵ\epsilon in O(nlog(1/ϵ))O(n\log(1/\epsilon)) measurements.

Keywords

Cite

@article{arxiv.2304.05960,
  title  = {Quantum Multi-Resolution Measurement with application to Quantum Linear Solver},
  author = {Yoshiyuki Saito and Xinwei Lee and Dongsheng Cai and Nobuyoshi Asai},
  journal= {arXiv preprint arXiv:2304.05960},
  year   = {2023}
}
R2 v1 2026-06-28T10:02:31.455Z