English

Quantum algorithms for systems of linear equations inspired by adiabatic quantum computing

Quantum Physics 2019-02-20 v2

Abstract

We present two quantum algorithms based on evolution randomization, a simple variant of adiabatic quantum computing, to prepare a quantum state x\vert x \rangle that is proportional to the solution of the system of linear equations Ax=bA \vec{x}=\vec{b}. The time complexities of our algorithms are O(κ2log(κ)/ϵ)O(\kappa^2 \log(\kappa)/\epsilon) and O(κlog(κ)/ϵ)O(\kappa \log(\kappa)/\epsilon), where κ\kappa is the condition number of AA and ϵ\epsilon is the precision. Both algorithms are constructed using families of Hamiltonians that are linear combinations of products of AA, the projector onto the initial state b\vert b \rangle, and single-qubit Pauli operators. The algorithms are conceptually simple and easy to implement. They are not obtained from equivalences between the gate model and adiabatic quantum computing. They do not use phase estimation or variable-time amplitude amplification, and do not require large ancillary systems. We discuss a gate-based implementation via Hamiltonian simulation and prove that our second algorithm is almost optimal in terms of κ\kappa. Like previous methods, our techniques yield an exponential quantum speedup under some assumptions. Our results emphasize the role of Hamiltonian-based models of quantum computing for the discovery of important algorithms.

Keywords

Cite

@article{arxiv.1805.10549,
  title  = {Quantum algorithms for systems of linear equations inspired by adiabatic quantum computing},
  author = {Yigit Subasi and Rolando D. Somma and Davide Orsucci},
  journal= {arXiv preprint arXiv:1805.10549},
  year   = {2019}
}

Comments

9 pages, 2 figures. Changes in version 2: - Includes a simpler algorithm for the special case of positive matrices. - Added pseudocode for the algorithms - Overall improved presentation

R2 v1 2026-06-23T02:09:25.332Z