We propose a reinforcement learning (RL) scheme for feedback quantum control within the quan-tum approximate optimization algorithm (QAOA). QAOA requires a variational minimization for states constructed by applying a sequence of unitary operators, depending on parameters living ina highly dimensional space. We reformulate such a minimum search as a learning task, where a RL agent chooses the control parameters for the unitaries, given partial information on the system. We show that our RL scheme finds a policy converging to the optimal adiabatic solution for QAOA found by Mbeng et al. arXiv:1906.08948 for the translationally invariant quantum Ising chain. In presence of disorder, we show that our RL scheme allows the training part to be performed on small samples, and transferred successfully on larger systems.
@article{arxiv.2004.12323,
title = {Reinforcement Learning assisted Quantum Optimization},
author = {Matteo M. Wauters and Emanuele Panizon and Glen B. Mbeng and Giuseppe E. Santoro},
journal= {arXiv preprint arXiv:2004.12323},
year = {2020}
}