We introduce an approach to improve the accuracy and reduce the sample complexity of near term quantum-classical algorithms. We construct a simpler initial parameterized quantum state, or ansatz, based on the past causal cone of each observable, generally yielding fewer qubits and gates. We implement this protocol on a trapped ion quantum computer and demonstrate improvement in accuracy and time-to-solution at an arbitrary point in the variational search space. We report a ∼27% improvement in the accuracy of the calculation of the deuteron binding energy and ∼40% improvement in the accuracy of the quantum approximate optimization of the MAXCUT problem applied to the dragon graph T3,2. When the time-to-solution is prioritized over accuracy, the former requires ∼71% fewer measurements and the latter requires ∼78% fewer measurements.
@article{arxiv.1906.00476,
title = {Noise reduction using past causal cones in variational quantum algorithms},
author = {Omar Shehab and Isaac H. Kim and Nhung H. Nguyen and Kevin Landsman and Cinthia H. Alderete and Daiwei Zhu and C. Monroe and Norbert M. Linke},
journal= {arXiv preprint arXiv:1906.00476},
year = {2019}
}
Comments
Added data availability statement, additional affiliation and grant acknowledgement