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Sample-optimal classical shadows for pure states

Quantum Physics 2024-06-19 v2 Information Theory Machine Learning math.IT

Abstract

We consider the classical shadows task for pure states in the setting of both joint and independent measurements. The task is to measure few copies of an unknown pure state ρ\rho in order to learn a classical description which suffices to later estimate expectation values of observables. Specifically, the goal is to approximate Tr(Oρ)\mathrm{Tr}(O \rho) for any Hermitian observable OO to within additive error ϵ\epsilon provided Tr(O2)B\mathrm{Tr}(O^2)\leq B and O=1\lVert O \rVert = 1. Our main result applies to the joint measurement setting, where we show Θ~(Bϵ1+ϵ2)\tilde{\Theta}(\sqrt{B}\epsilon^{-1} + \epsilon^{-2}) samples of ρ\rho are necessary and sufficient to succeed with high probability. The upper bound is a quadratic improvement on the previous best sample complexity known for this problem. For the lower bound, we see that the bottleneck is not how fast we can learn the state but rather how much any classical description of ρ\rho can be compressed for observable estimation. In the independent measurement setting, we show that O(Bdϵ1+ϵ2)\mathcal O(\sqrt{Bd} \epsilon^{-1} + \epsilon^{-2}) samples suffice. Notably, this implies that the random Clifford measurements algorithm of Huang, Kueng, and Preskill, which is sample-optimal for mixed states, is not optimal for pure states. Interestingly, our result also uses the same random Clifford measurements but employs a different estimator.

Keywords

Cite

@article{arxiv.2211.11810,
  title  = {Sample-optimal classical shadows for pure states},
  author = {Daniel Grier and Hakop Pashayan and Luke Schaeffer},
  journal= {arXiv preprint arXiv:2211.11810},
  year   = {2024}
}

Comments

34 pages; v2 - journal version

R2 v1 2026-06-28T06:24:46.203Z