Improved bounded-strength decoupling schemes for local Hamiltonians
Abstract
We address the task of switching off the Hamiltonian of a system by removing all internal and system-environment couplings. We propose dynamical decoupling schemes, that use only bounded-strength controls, for quantum many-body systems with local system Hamiltonians and local environmental couplings. To do so, we introduce the combinatorial concept of balanced-cycle orthogonal arrays (BOAs) and show how to construct them from classical error-correcting codes. The derived decoupling schemes may be useful as a primitive for more complex schemes, e.g., for Hamiltonian simulation. For the case of qubits and a -local Hamiltonian, the length of the resulting decoupling scheme scales as , improving over the previously best-known schemes that scaled quadratically with . More generally, using balanced-cycle orthogonal arrays constructed from families of BCH codes, we show that bounded-strength decoupling for any -local Hamiltonian, where , can be achieved using decoupling schemes of length at most .
Cite
@article{arxiv.1509.00408,
title = {Improved bounded-strength decoupling schemes for local Hamiltonians},
author = {Adam D. Bookatz and Martin Roetteler and Pawel Wocjan},
journal= {arXiv preprint arXiv:1509.00408},
year = {2016}
}
Comments
18 pages; added explanatory examples (with figures)