English

Boson sampling with Gaussian measurements

Quantum Physics 2017-09-19 v4

Abstract

We develop an alternative boson sampling model operating on single-photon states followed by linear interferometry and Gaussian measurements. The hardness proof for simulating such continuous-variable measurements is established in two main steps, making use of the symmetry of quantum evolution under time reversal. Namely, we first construct a twofold version of scattershot boson sampling in which, as opposed to the original proposal, both legs of a collection of two-mode squeezed vacuum states undergo parallel linear-optical transformations. This twofold scattershot model yields, as a corollary, an instance of boson sampling from Gaussian states where photon counting is hard to simulate. Then, a time-reversed setup is used to exhibit a boson sampling model in which the simulation of Gaussian measurements -- namely the outcome of eight-port homodyne detection -- is proven to be computationally hard. These results illustrate how the symmetry of quantum evolution under time reversal may serve as a tool for analyzing the computational complexity of novel physically-motivated computational problems.

Keywords

Cite

@article{arxiv.1705.05299,
  title  = {Boson sampling with Gaussian measurements},
  author = {Levon Chakhmakhchyan and Nicolas J. Cerf},
  journal= {arXiv preprint arXiv:1705.05299},
  year   = {2017}
}

Comments

8 pages, 3 figures. Updated version for publication

R2 v1 2026-06-22T19:47:26.560Z