Shorter gate sequences for quantum computing by mixing unitaries
Quantum Physics
2017-04-12 v3
Abstract
Fault-tolerant quantum computers compose elements of a discrete gate set in order to approximate a target unitary. The problem of minimising the number of gates is known as gate-synthesis. The approximation error is a form of coherent noise, which can be significantly more damaging than comparable incoherent noise. We show how mixing over different gate sequences can convert this coherent noise into an incoherent form. As measured by diamond distance, the post-mixing noise is quadratically smaller than before mixing, with no additional resource cost. Equivalently, we can use a shorter gate sequence to achieve the same precision as unitary gate-synthesis, with a factor 1/2 reduction for a broad class of problems.
Cite
@article{arxiv.1612.02689,
title = {Shorter gate sequences for quantum computing by mixing unitaries},
author = {Earl Campbell},
journal= {arXiv preprint arXiv:1612.02689},
year = {2017}
}
Comments
Author's final copy