In this work we combine two distinct machine learning methodologies, sequential Monte Carlo and Bayesian experimental design, and apply them to the problem of inferring the dynamical parameters of a quantum system. We design the algorithm with practicality in mind by including parameters that control trade-offs between the requirements on computational and experimental resources. The algorithm can be implemented online (during experimental data collection), avoiding the need for storage and post-processing. Most importantly, our algorithm is capable of learning Hamiltonian parameters even when the parameters change from experiment-to-experiment, and also when additional noise processes are present and unknown. The algorithm also numerically estimates the Cramer-Rao lower bound, certifying its own performance.
@article{arxiv.1207.1655,
title = {Robust Online Hamiltonian Learning},
author = {Christopher E. Granade and Christopher Ferrie and Nathan Wiebe and D. G. Cory},
journal= {arXiv preprint arXiv:1207.1655},
year = {2012}
}
Comments
24 pages, 12 figures; to appear in New Journal of Physics