The efficient validation of quantum devices is critical for emerging technological applications. In a wide class of use-cases the precise engineering of a Hamiltonian is required both for the implementation of gate-based quantum information processing as well as for reliable quantum memories. Inferring the experimentally realized Hamiltonian through a scalable number of measurements constitutes the challenging task of Hamiltonian learning. In particular, assessing the quality of the implementation of topological codes is essential for quantum error correction. Here, we introduce a neural net based approach to this challenge. We capitalize on a family of exactly solvable models to train our algorithm and generalize to a broad class of experimentally relevant sources of errors. We discuss how our algorithm scales with system size and analyze its resilience towards various noise sources.
@article{arxiv.1907.02540,
title = {Hamiltonian Learning for Quantum Error Correction},
author = {Agnes Valenti and Evert van Nieuwenburg and Sebastian Huber and Eliska Greplova},
journal= {arXiv preprint arXiv:1907.02540},
year = {2019}
}
Comments
15 pages, 12 figures. Code available at https://github.com/cmt-qo/cm-toricCode