English

Designing quantum experiments with a genetic algorithm

Quantum Physics 2023-05-01 v2 Artificial Intelligence Machine Learning Neural and Evolutionary Computing

Abstract

We introduce a genetic algorithm that designs quantum optics experiments for engineering quantum states with specific properties. Our algorithm is powerful and flexible, and can easily be modified to find methods of engineering states for a range of applications. Here we focus on quantum metrology. First, we consider the noise-free case, and use the algorithm to find quantum states with a large quantum Fisher information (QFI). We find methods, which only involve experimental elements that are available with current or near-future technology, for engineering quantum states with up to a 100-fold improvement over the best classical state, and a 20-fold improvement over the optimal Gaussian state. Such states are a superposition of the vacuum with a large number of photons (around 8080), and can hence be seen as Schr\"odinger-cat-like states. We then apply the two most dominant noise sources in our setting -- photon loss and imperfect heralding -- and use the algorithm to find quantum states that still improve over the optimal Gaussian state with realistic levels of noise. This will open up experimental and technological work in using exotic non-Gaussian states for quantum-enhanced phase measurements. Finally, we use the Bayesian mean square error to look beyond the regime of validity of the QFI, finding quantum states with precision enhancements over the alternatives even when the experiment operates in the regime of limited data.

Keywords

Cite

@article{arxiv.1812.01032,
  title  = {Designing quantum experiments with a genetic algorithm},
  author = {Rosanna Nichols and Lana Mineh and Jesús Rubio and Jonathan C. F. Matthews and Paul A. Knott},
  journal= {arXiv preprint arXiv:1812.01032},
  year   = {2023}
}

Comments

11 pages + Appendix, 9 figures

R2 v1 2026-06-23T06:30:01.838Z