Quantum optical neural networks for next generation quantum information processing

ORAL

Abstract

Physically motivated quantum algorithms for specific near-term quantum hardware will likely be the next frontier in quantum information science. Here, we show how many of the features of neural networks for machine learning can naturally be mapped into the quantum optical domain by introducing the quantum optical neural network (QONN). Through numerical simulation and analysis we train the QONN to perform a range of quantum information processing tasks, including protocols for quantum optical state compression, reinforcement learning, and black-box quantum simulation. Our results indicate QONNs are a powerful design tool for quantum optical systems and a promising architecture for next generation quantum processors.

*This work was supported by the AFOSR MURI for Optimal Measurements for Scalable Quantum Technologies (FA9550-14-1-0052) and by the AFOSR program FA9550-16-1-0391, supervised by Gernot Pomrenke. G.R.S. acknowledges support from the Facebook Fellowship Program. J.C. is supported by EU H2020 Marie Sklodowska-Curie grant number 751016. We gratefully acknowledge the support of NVIDIA Corporation with the donation of the Tesla K40 GPU used for this research.

Presenters

  • Jonathan Olson

    • Zapata Computing

Authors

  • Gregory R Steinbrecher

    • Research Laboratory of Electronics, Massachusetts Institute of Technology

  • Jonathan Olson

    • Zapata Computing

  • Dirk R. Englund

    • Electrical Engineering and Computer Science, MIT
    • Massachusetts Institute of Technology
    • MIT
    • EECS, MIT
    • Electrical Engineering and Computer Science, Massachusetts Institute of Technology
    • Research Laboratory of Electronics, Massachusetts Institute of Technology

  • Jacques Carolan

    • Research Laboratory of Electronics, Massachusetts Institute of Technology