Abstract
Hybrid quantum-classical algorithms provide ways to use noisy intermediate-scale quantum computers for practical applications. Expanding the portfolio of such techniques, we propose a quantum circuit learning algorithm that can be used to assist the characterization of quantum devices and to train shallow circuits for generative tasks. The procedure leverages quantum hardware capabilities to its fullest extent by using native gates and their qubit connectivity. We demonstrate that our approach can learn an optimal preparation of the Greenberger-Horne-Zeilinger states, also known as “cat states”. We further demonstrate that our approach can efficiently prepare approximate representations of coherent thermal states, wave functions that encode Boltzmann probabilities in their amplitudes. Finally, complementing proposals to characterize the power or usefulness of near-term quantum devices, such as IBM’s quantum volume, we provide a new hardware-independent metric called the qBAS score. It is based on the performance yield in a specific sampling task on one of the canonical machine learning data sets known as Bars and Stripes. We show how entanglement is a key ingredient in encoding the patterns of this data set; an ideal benchmark for testing hardware starting at four qubits and up. We provide experimental results and evaluation of this metric to probe the trade off between several architectural circuit designs and circuit depths on an ion-trap quantum computer.
Original language | English |
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Article number | 45 |
Journal | npj Quantum Information |
Volume | 5 |
Issue number | 1 |
DOIs | |
State | Published - Dec 1 2019 |
Externally published | Yes |
Funding
M.B. was supported by the UK Engineering and Physical Sciences Research Council (EPSRC) and by Cambridge Quantum Computing Limited (CQCL). The authors are very grateful to Prof. Christopher Monroe and his team at the University of Maryland (UMD) for their support in running the experiments presented here. Special thanks to N.M. Linke, C. Figgatt, K.A. Landsman, and D. Zhu for useful discussions and for running the several experiments used to test and validate the pipeline of this work, and the ones presented in the “Results” section. The authors acknowledge E. Edwards from the communications/publicity division at the Joint Quantum Institute at UMD for the rendering of the ion-trap graphic used in Fig. 2, and would like to thank J. Realpe-Gomez, A.M. Wilson, and G. Paz-Silva for useful discussions and feedback on an early version of this manuscript. The authors would like to thank J.I. Latorre for pointing out ref.56.
Funders | Funder number |
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Cambridge Quantum Computing Limited | |
Engineering and Physical Sciences Research Council |