English

Random quantum circuits transform local noise into global white noise

Quantum Physics 2021-12-01 v1

Abstract

We study the distribution over measurement outcomes of noisy random quantum circuits in the low-fidelity regime. We show that, for local noise that is sufficiently weak and unital, correlations (measured by the linear cross-entropy benchmark) between the output distribution pnoisyp_{\text{noisy}} of a generic noisy circuit instance and the output distribution pidealp_{\text{ideal}} of the corresponding noiseless instance shrink exponentially with the expected number of gate-level errors, as F=exp(2sϵ±O(sϵ2))F=\text{exp}(-2s\epsilon \pm O(s\epsilon^2)), where ϵ\epsilon is the probability of error per circuit location and ss is the number of two-qubit gates. Furthermore, if the noise is incoherent, the output distribution approaches the uniform distribution punifp_{\text{unif}} at precisely the same rate and can be approximated as pnoisyFpideal+(1F)punifp_{\text{noisy}} \approx Fp_{\text{ideal}} + (1-F)p_{\text{unif}}, that is, local errors are scrambled by the random quantum circuit and contribute only white noise (uniform output). Importantly, we upper bound the total variation error (averaged over random circuit instance) in this approximation as O(Fϵs)O(F\epsilon \sqrt{s}), so the "white-noise approximation" is meaningful when ϵs1\epsilon \sqrt{s} \ll 1, a quadratically weaker condition than the ϵs1\epsilon s\ll 1 requirement to maintain high fidelity. The bound applies when the circuit size satisfies sΩ(nlog(n))s \geq \Omega(n\log(n)) and the inverse error rate satisfies ϵ1Ω~(n)\epsilon^{-1} \geq \tilde{\Omega}(n). The white-noise approximation is useful for salvaging the signal from a noisy quantum computation; it was an underlying assumption in complexity-theoretic arguments that low-fidelity random quantum circuits cannot be efficiently sampled classically. Our method is based on a map from second-moment quantities in random quantum circuits to expectation values of certain stochastic processes for which we compute upper and lower bounds.

Keywords

Cite

@article{arxiv.2111.14907,
  title  = {Random quantum circuits transform local noise into global white noise},
  author = {Alexander M. Dalzell and Nicholas Hunter-Jones and Fernando G. S. L. Brandão},
  journal= {arXiv preprint arXiv:2111.14907},
  year   = {2021}
}

Comments

76 pages, 6 figures

R2 v1 2026-06-24T07:56:36.042Z