Nature Communications (Jul 2023)

Deep quantum neural networks on a superconducting processor

  • Xiaoxuan Pan,
  • Zhide Lu,
  • Weiting Wang,
  • Ziyue Hua,
  • Yifang Xu,
  • Weikang Li,
  • Weizhou Cai,
  • Xuegang Li,
  • Haiyan Wang,
  • Yi-Pu Song,
  • Chang-Ling Zou,
  • Dong-Ling Deng,
  • Luyan Sun

DOI
https://doi.org/10.1038/s41467-023-39785-8
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 7

Abstract

Read online

Abstract Deep learning and quantum computing have achieved dramatic progresses in recent years. The interplay between these two fast-growing fields gives rise to a new research frontier of quantum machine learning. In this work, we report an experimental demonstration of training deep quantum neural networks via the backpropagation algorithm with a six-qubit programmable superconducting processor. We experimentally perform the forward process of the backpropagation algorithm and classically simulate the backward process. In particular, we show that three-layer deep quantum neural networks can be trained efficiently to learn two-qubit quantum channels with a mean fidelity up to 96.0% and the ground state energy of molecular hydrogen with an accuracy up to 93.3% compared to the theoretical value. In addition, six-layer deep quantum neural networks can be trained in a similar fashion to achieve a mean fidelity up to 94.8% for learning single-qubit quantum channels. Our experimental results indicate that the number of coherent qubits required to maintain does not scale with the depth of the deep quantum neural network, thus providing a valuable guide for quantum machine learning applications with both near-term and future quantum devices.