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Meta Hamiltonian Learning

Quantum Physics 2021-04-12 v1 Quantum Gases Atomic Physics

Abstract

Efficient characterization of quantum devices is a significant challenge critical for the development of large scale quantum computers. We consider an experimentally motivated situation, in which we have a decent estimate of the Hamiltonian, and its parameters need to be characterized and fine-tuned frequently to combat drifting experimental variables. We use a machine learning technique known as meta-learning to learn a more efficient optimizer for this task. We consider training with the nearest-neighbor Ising model and study the trained model's generalizability to other Hamiltonian models and larger system sizes. We observe that the meta-optimizer outperforms other optimization methods in average loss over test samples. This advantage follows from the meta-optimizer being less likely to get stuck in local minima, which highly skews the distribution of the final loss of the other optimizers. In general, meta-learning decreases the number of calls to the experiment and reduces the needed classical computational resources.

Keywords

Cite

@article{arxiv.2104.04453,
  title  = {Meta Hamiltonian Learning},
  author = {Przemyslaw Bienias and Alireza Seif and Mohammad Hafezi},
  journal= {arXiv preprint arXiv:2104.04453},
  year   = {2021}
}
R2 v1 2026-06-24T01:00:42.254Z