English

Parametrized quantum policies for reinforcement learning

Quantum Physics 2021-12-10 v2 Artificial Intelligence Machine Learning Machine Learning

Abstract

With the advent of real-world quantum computing, the idea that parametrized quantum computations can be used as hypothesis families in a quantum-classical machine learning system is gaining increasing traction. Such hybrid systems have already shown the potential to tackle real-world tasks in supervised and generative learning, and recent works have established their provable advantages in special artificial tasks. Yet, in the case of reinforcement learning, which is arguably most challenging and where learning boosts would be extremely valuable, no proposal has been successful in solving even standard benchmarking tasks, nor in showing a theoretical learning advantage over classical algorithms. In this work, we achieve both. We propose a hybrid quantum-classical reinforcement learning model using very few qubits, which we show can be effectively trained to solve several standard benchmarking environments. Moreover, we demonstrate, and formally prove, the ability of parametrized quantum circuits to solve certain learning tasks that are intractable for classical models, including current state-of-art deep neural networks, under the widely-believed classical hardness of the discrete logarithm problem.

Keywords

Cite

@article{arxiv.2103.05577,
  title  = {Parametrized quantum policies for reinforcement learning},
  author = {Sofiene Jerbi and Casper Gyurik and Simon C. Marshall and Hans J. Briegel and Vedran Dunjko},
  journal= {arXiv preprint arXiv:2103.05577},
  year   = {2021}
}

Comments

NeurIPS 2021 camera-ready version

R2 v1 2026-06-23T23:55:43.189Z