English

Quantum algorithm for systems of linear equations with exponentially improved dependence on precision

Quantum Physics 2017-12-27 v2

Abstract

Harrow, Hassidim, and Lloyd showed that for a suitably specified N×NN \times N matrix AA and NN-dimensional vector b\vec{b}, there is a quantum algorithm that outputs a quantum state proportional to the solution of the linear system of equations Ax=bA\vec{x}=\vec{b}. If AA is sparse and well-conditioned, their algorithm runs in time poly(logN,1/ϵ)\mathrm{poly}(\log N, 1/\epsilon), where ϵ\epsilon is the desired precision in the output state. We improve this to an algorithm whose running time is polynomial in log(1/ϵ)\log(1/\epsilon), exponentially improving the dependence on precision while keeping essentially the same dependence on other parameters. Our algorithm is based on a general technique for implementing any operator with a suitable Fourier or Chebyshev series representation. This allows us to bypass the quantum phase estimation algorithm, whose dependence on ϵ\epsilon is prohibitive.

Keywords

Cite

@article{arxiv.1511.02306,
  title  = {Quantum algorithm for systems of linear equations with exponentially improved dependence on precision},
  author = {Andrew M. Childs and Robin Kothari and Rolando D. Somma},
  journal= {arXiv preprint arXiv:1511.02306},
  year   = {2017}
}

Comments

v1: 28 pages; v2: 31 pages, minor change to title, various minor changes and clarifications in response to referee comments

R2 v1 2026-06-22T11:39:33.221Z