Optimal arbitrarily accurate composite pulse sequences
Abstract
Implementing a single qubit unitary is often hampered by imperfect control. Systematic amplitude errors , caused by incorrect duration or strength of a pulse, are an especially common problem. But a sequence of imperfect pulses can provide a better implementation of a desired operation, as compared to a single primitive pulse. We find optimal pulse sequences consisting of primitive or rotations that suppress such errors to arbitrary order on arbitrary initial states. Optimality is demonstrated by proving an lower bound and saturating it with solutions. Closed-form solutions for arbitrary rotation angles are given for . Perturbative solutions for any are proven for small angles, while arbitrary angle solutions are obtained by analytic continuation up to . The derivation proceeds by a novel algebraic and non-recursive approach, in which finding amplitude error correcting sequences can be reduced to solving polynomial equations.
Keywords
Cite
@article{arxiv.1307.2211,
title = {Optimal arbitrarily accurate composite pulse sequences},
author = {Guang Hao Low and Theodore J. Yoder and Isaac L. Chuang},
journal= {arXiv preprint arXiv:1307.2211},
year = {2014}
}
Comments
12 pages, 5 figures, submitted to Physical Review A