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Foundations for learning from noisy quantum experiments

Quantum Physics 2022-04-29 v1 Information Theory Machine Learning math.IT

Abstract

Understanding what can be learned from experiments is central to scientific progress. In this work, we use a learning-theoretic perspective to study the task of learning physical operations in a quantum machine when all operations (state preparation, dynamics, and measurement) are a priori unknown. We prove that, without any prior knowledge, if one can explore the full quantum state space by composing the operations, then every operation can be learned. When one cannot explore the full state space but all operations are approximately known and noise in Clifford gates is gate-independent, we find an efficient algorithm for learning all operations up to a single unlearnable parameter characterizing the fidelity of the initial state. For learning a noise channel on Clifford gates to a fixed accuracy, our algorithm uses quadratically fewer experiments than previously known protocols. Under more general conditions, the true description of the noise can be unlearnable; for example, we prove that no benchmarking protocol can learn gate-dependent Pauli noise on Clifford+T gates even under perfect state preparation and measurement. Despite not being able to learn the noise, we show that a noisy quantum computer that performs entangled measurements on multiple copies of an unknown state can yield a large advantage in learning properties of the state compared to a noiseless device that measures individual copies and then processes the measurement data using a classical computer. Concretely, we prove that noisy quantum computers with two-qubit gate error rate ϵ\epsilon can achieve a learning task using NN copies of the state, while NΩ(1/ϵ)N^{\Omega(1/\epsilon)} copies are required classically.

Keywords

Cite

@article{arxiv.2204.13691,
  title  = {Foundations for learning from noisy quantum experiments},
  author = {Hsin-Yuan Huang and Steven T. Flammia and John Preskill},
  journal= {arXiv preprint arXiv:2204.13691},
  year   = {2022}
}

Comments

10 pages, 1 figure + 70 page appendix

R2 v1 2026-06-24T11:01:53.146Z