Quantum (May 2024)

Hybrid discrete-continuous compilation of trapped-ion quantum circuits with deep reinforcement learning

  • Francesco Preti,
  • Michael Schilling,
  • Sofiene Jerbi,
  • Lea M. Trenkwalder,
  • Hendrik Poulsen Nautrup,
  • Felix Motzoi,
  • Hans J. Briegel

DOI
https://doi.org/10.22331/q-2024-05-14-1343
Journal volume & issue
Vol. 8
p. 1343

Abstract

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Shortening quantum circuits is crucial to reducing the destructive effect of environmental decoherence and enabling useful algorithms. Here, we demonstrate an improvement in such compilation tasks via a combination of using hybrid discrete-continuous optimization across a continuous gate set, and architecture-tailored implementation. The continuous parameters are discovered with a gradient-based optimization algorithm, while in tandem the optimal gate orderings are learned via a deep reinforcement learning algorithm, based on projective simulation. To test this approach, we introduce a framework to simulate collective gates in trapped-ion systems efficiently on a classical device. The algorithm proves able to significantly reduce the size of relevant quantum circuits for trapped-ion computing. Furthermore, we show that our framework can also be applied to an experimental setup whose goal is to reproduce an unknown unitary process.