An iterative quantum-phase-estimation protocol for near-term quantum hardware

Abstract

Given Ntot applications of a unitary operation with an unknown phase θ, a large-scale fault-tolerant quantum system can reduce an estimate's error scaling from O [ 1 / Ntot ] to O [ 1 / Ntot ]. Owing to the limited resources available to near-term quantum devices, entanglement-free protocols have been developed, which achieve a O [ (Ntot) / Ntot ] mean-absolute-error scaling. Here, we propose a new two-step protocol for near-term phase estimation, with an improved error scaling. Our protocol's first step produces several low-standard-deviation estimates of θ , within θ's parameter range. The second step iteratively hones in on one of these estimates. Our protocol's mean absolute error scales as O [ ( Ntot) / Ntot ]. Furthermore, we demonstrate a reduction in the constant scaling factor and the required circuit depths: our protocol can outperform the asymptotically optimal quantum-phase estimation algorithm for realistic values of Ntot.