State-dependent Routing Dynamics in Noisy Quantum Computing Devices
Abstract
Routing plays an important role in programming noisy, intermediate-scale quantum (NISQ) devices, where limited connectivity in the register is overcome by swapping quantum information between locations. However, routing a quantum state using noisy gates introduces non-trivial noise dynamics, and deciding on an optimal route to minimize accumulated error requires estimates of the expected state fidelity. Here we validate a model for state-dependent routing dynamics in a NISQ processor based on correlated binary noise. We develop a composable, state-dependent noise model for CNOT and SWAP operations that can be characterized efficiently using pair-wise experimental measurements, and we compare model predictions with tomographic state reconstructions recovered from a quantum device. These results capture the state-dependent routing dynamics that are needed to guide routing decisions for near-real time operation of NISQ devices.
Cite
@article{arxiv.2012.13131,
title = {State-dependent Routing Dynamics in Noisy Quantum Computing Devices},
author = {Ronald J. Sadlier and Travis S. Humble},
journal= {arXiv preprint arXiv:2012.13131},
year = {2021}
}
Comments
In memoriam Ron Sadlier