Measurement-driven quantum computing: Performance of a 3-SAT solver
Abstract
We investigate the performance of a quantum algorithm for solving classical 3-SAT problems. A cycle of post-selected measurements drives the computer's register monotonically toward a steady state which is correlated to the classical solution(s). An internal parameter determines both the degree of correlation and the success probability, thus controlling the algorithm's runtime. Optionally this parameter can be gradually evolved during the algorithm's execution to create a Zeno-like effect; this can be viewed as an adiabatic evolution of a Hamiltonian which remains frustration-free at all points, and we lower-bound the corresponding gap. In exact numerical simulations of small systems up to 34 qubits our approach competes favourably with a high-performing classical 3-SAT solver, which itself outperforms a brute-force application of Grover's search.
Cite
@article{arxiv.1711.02687,
title = {Measurement-driven quantum computing: Performance of a 3-SAT solver},
author = {Simon C. Benjamin and Liming Zhao and Joseph F. Fitzsimons},
journal= {arXiv preprint arXiv:1711.02687},
year = {2017}
}
Comments
16 pages, 9 figs