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Performance analysis of multi-shot shadow estimation

Quantum Physics 2023-07-05 v2

Abstract

Shadow estimation is an efficient method for predicting many observables of a quantum state with a statistical guarantee. In the multi-shot scenario, one performs projective measurement on the sequentially prepared state for KK times after the same unitary evolution, and repeats this procedure for MM rounds of random sampled unitary. As a result, there are MKMK times measurements in total. Here we analyze the performance of shadow estimation in this multi-shot scenario, which is characterized by the variance of estimating the expectation value of some observable OO. We find that in addition to the shadow-norm Oshadow\|O \|_{\mathrm{shadow}} introduced in [Huang et.al.~Nat.~Phys.~2020\cite{huang2020predicting}], the variance is also related to another norm, and we denote it as the cross-shadow-norm OXshadow\|O \|_{\mathrm{Xshadow}}. For both random Pauli and Clifford measurements, we analyze and show the upper bounds of OXshadow\|O \|_{\mathrm{Xshadow}}. In particular, we figure out the exact variance formula for Pauli observable under random Pauli measurements. Our work gives theoretical guidance for the application of multi-shot shadow estimation.

Cite

@article{arxiv.2212.11068,
  title  = {Performance analysis of multi-shot shadow estimation},
  author = {You Zhou and Qing Liu},
  journal= {arXiv preprint arXiv:2212.11068},
  year   = {2023}
}

Comments

Discussions on measuring a collection of observables and details on numerical simulation are added

R2 v1 2026-06-28T07:46:58.643Z