Classical shadows based on locally-entangled measurements
Abstract
We study classical shadows protocols based on randomized measurements in -qubit entangled bases, generalizing the random Pauli measurement protocol (). We show that entangled measurements () enable nontrivial and potentially advantageous trade-offs in the sample complexity of learning Pauli expectation values. This is sharply illustrated by shadows based on two-qubit Bell measurements: the scaling of sample complexity with Pauli weight improves quadratically (from down to ) for many operators, while others become impossible to learn. Tuning the amount of entanglement in the measurement bases defines a family of protocols that interpolate between Pauli and Bell shadows, retaining some of the benefits of both. For large , we show that randomized measurements in -qubit GHZ bases further improve the best scaling to , albeit on an increasingly restricted set of operators. Despite their simplicity and lower hardware requirements, these protocols can match or outperform recently-introduced "shallow shadows" in some practically-relevant Pauli estimation tasks.
Cite
@article{arxiv.2305.10723,
title = {Classical shadows based on locally-entangled measurements},
author = {Matteo Ippoliti},
journal= {arXiv preprint arXiv:2305.10723},
year = {2024}
}
Comments
8 pages, 3 figures. v2: added discussion of operators with non-contiguous support in 1D, reference to Shor-Laflamme distributions, minor improvements. v3: fixed typos, added some references and clarified some derivations. Accepted in Quantum