Variational Quantum Unsampling on a Quantum Photonic Processor
Abstract
Quantum algorithms for Noisy Intermediate-Scale Quantum (NISQ) machines have recently emerged as new promising routes towards demonstrating near-term quantum advantage (or supremacy) over classical systems. In these systems samples are typically drawn from probability distributions which --- under plausible complexity-theoretic conjectures --- cannot be efficiently generated classically. Rather than first define a physical system and then determine computational features of the output state, we ask the converse question: given direct access to the quantum state, what features of the generating system can we efficiently learn? In this work we introduce the Variational Quantum Unsampling (VQU) protocol, a nonlinear quantum neural network approach for verification and inference of near-term quantum circuits outputs. In our approach one can variationally train a quantum operation to unravel the action of an unknown unitary on a known input state; essentially learning the inverse of the black-box quantum dynamics. While the principle of our approach is platform independent, its implementation will depend on the unique architecture of a specific quantum processor. Here, we experimentally demonstrate the VQU protocol on a quantum photonic processor. Alongside quantum verification, our protocol has broad applications; including optimal quantum measurement and tomography, quantum sensing and imaging, and ansatz validation.
Cite
@article{arxiv.1904.10463,
title = {Variational Quantum Unsampling on a Quantum Photonic Processor},
author = {Jacques Carolan and Masoud Mohseni and Jonathan P. Olson and Mihika Prabhu and Changchen Chen and Darius Bunandar and Nicholas C. Harris and Franco N. C. Wong and Michael Hochberg and Seth Lloyd and Dirk Englund},
journal= {arXiv preprint arXiv:1904.10463},
year = {2021}
}
Comments
Comments welcome. Updates references and acknowledgements