Quantitative tomography for continuous variable quantum systems
Abstract
We present a continuous variable tomography scheme that reconstructs the Husimi Q-function (Wigner function) by Lagrange interpolation, using measurements of the Q-function (Wigner function) at the Padua points, the optimal sampling points for two dimensional reconstruction. Our approach drastically reduces the number of measurements required compared to using equidistant points on a regular grid, although reanalysis of such experiments is possible. The reconstruction algorithm produces a reconstructed function with exponentially decreasing error and quasi-linear runtime in the number of Padua points. Moreover, using the interpolating polynomial of the Q-function, we present a technique to directly estimate the density matrix elements of the continuous variable state, with only linear propagation of input measurement error. Furthermore, we derive a state-independent analytical bound on this error, such that our estimate of the density matrix is accompanied by a measure of its uncertainty.
Cite
@article{arxiv.1706.07816,
title = {Quantitative tomography for continuous variable quantum systems},
author = {Olivier Landon-Cardinal and Luke C. G. Govia and Aashish A. Clerk},
journal= {arXiv preprint arXiv:1706.07816},
year = {2018}
}
Comments
4.25 pages, 2 figures (+ 3.5 pages, 4 figures)