Twirling and Hamiltonian Engineering via Dynamical Decoupling for GKP Quantum Computing
Quantum Physics
2021-02-10 v3
Abstract
I introduce an energy constrained approximate twirling operation that can be used to diagonalize effective logical channels in GKP quantum error correction, project states into the GKP code space and construct a dynamical decoupling sequence with fast displacements pulses to distill the GKP stabilizer Hamiltonians from a suitable substrate-Hamiltonian. The latter is given by an LC-oscillator comprising a superinductance in parallel to a Josephson Junction. This platform in principle allows for protected GKP quantum computing without explicit stabilizer measurements or state-reset by dynamically generating a `passively' stabilized GKP qubit.
Keywords
Cite
@article{arxiv.2010.13853,
title = {Twirling and Hamiltonian Engineering via Dynamical Decoupling for GKP Quantum Computing},
author = {Jonathan Conrad},
journal= {arXiv preprint arXiv:2010.13853},
year = {2021}
}
Comments
13+4 pages, 6 figures, Comments and feedback welcome! v3 with corrected typos and updated references