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Optimal quantum dataset for learning a unitary transformation

Quantum Physics 2023-03-09 v3 Machine Learning High Energy Physics - Theory

Abstract

Unitary transformations formulate the time evolution of quantum states. How to learn a unitary transformation efficiently is a fundamental problem in quantum machine learning. The most natural and leading strategy is to train a quantum machine learning model based on a quantum dataset. Although the presence of more training data results in better models, using too much data reduces the efficiency of training. In this work, we solve the problem on the minimum size of sufficient quantum datasets for learning a unitary transformation exactly, which reveals the power and limitation of quantum data. First, we prove that the minimum size of a dataset with pure states is 2n2^n for learning an nn-qubit unitary transformation. To fully explore the capability of quantum data, we introduce a practical quantum dataset consisting of n+1n+1 elementary tensor product states that are sufficient for exact training. The main idea is to simplify the structure utilizing decoupling, which leads to an exponential improvement in the size of the datasets with pure states. Furthermore, we show that the size of the quantum dataset with mixed states can be reduced to a constant, which yields an optimal quantum dataset for learning a unitary. We showcase the applications of our results in oracle compiling and Hamiltonian simulation. Notably, to accurately simulate a 3-qubit one-dimensional nearest-neighbor Heisenberg model, our circuit only uses 9696 elementary quantum gates, which is significantly less than 40804080 gates in the circuit constructed by the Trotter-Suzuki product formula.

Keywords

Cite

@article{arxiv.2203.00546,
  title  = {Optimal quantum dataset for learning a unitary transformation},
  author = {Zhan Yu and Xuanqiang Zhao and Benchi Zhao and Xin Wang},
  journal= {arXiv preprint arXiv:2203.00546},
  year   = {2023}
}

Comments

11 pages including appendix, v2 added remarks and references, v3 is closed to the published version

R2 v1 2026-06-24T09:58:05.237Z