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Learning shallow quantum circuits

Quantum Physics 2024-06-13 v1 Information Theory Machine Learning math.IT

Abstract

Despite fundamental interests in learning quantum circuits, the existence of a computationally efficient algorithm for learning shallow quantum circuits remains an open question. Because shallow quantum circuits can generate distributions that are classically hard to sample from, existing learning algorithms do not apply. In this work, we present a polynomial-time classical algorithm for learning the description of any unknown nn-qubit shallow quantum circuit UU (with arbitrary unknown architecture) within a small diamond distance using single-qubit measurement data on the output states of UU. We also provide a polynomial-time classical algorithm for learning the description of any unknown nn-qubit state ψ=U0n\lvert \psi \rangle = U \lvert 0^n \rangle prepared by a shallow quantum circuit UU (on a 2D lattice) within a small trace distance using single-qubit measurements on copies of ψ\lvert \psi \rangle. Our approach uses a quantum circuit representation based on local inversions and a technique to combine these inversions. This circuit representation yields an optimization landscape that can be efficiently navigated and enables efficient learning of quantum circuits that are classically hard to simulate.

Keywords

Cite

@article{arxiv.2401.10095,
  title  = {Learning shallow quantum circuits},
  author = {Hsin-Yuan Huang and Yunchao Liu and Michael Broughton and Isaac Kim and Anurag Anshu and Zeph Landau and Jarrod R. McClean},
  journal= {arXiv preprint arXiv:2401.10095},
  year   = {2024}
}

Comments

10 pages, 14 figures (7 inline; 7 floating) + 76-page appendix

R2 v1 2026-06-28T14:20:34.826Z