English

Simulating quantum circuits with arbitrary local noise using Pauli Propagation

Quantum Physics 2026-04-23 v2

Abstract

We present a polynomial-time classical algorithm for estimating expectation values of arbitrary observables on typical quantum circuits under any incoherent local noise, including non-unital or dephasing. Although previous research demonstrated that some carefully designed quantum circuits affected by non-unital noise cannot be efficiently simulated, we show that this does not apply to average-case circuits, as these can be efficiently simulated using Pauli-path methods. Specifically, we prove that, with high probability over the circuit gates choice, Pauli propagation algorithms with tailored truncation strategies achieve an inversely polynomially small simulation error. This result holds for arbitrary circuit topologies and for any local noise, under the assumption that the distribution of each circuit layer is invariant under single-qubit random gates. Under the same minimal assumptions, we also prove that most noisy circuits can be truncated to an effective logarithmic depth for the task of {estimating} expectation values of observables, thus generalizing prior results to a significantly broader class of circuit ensembles. We further numerically validate our algorithm with simulations on a 6×66\times6 lattice of qubits under the effects of amplitude damping and dephasing noise, as well as real-time dynamics on an 11×1111\times11 lattice of qubits affected by amplitude damping.

Keywords

Cite

@article{arxiv.2501.13101,
  title  = {Simulating quantum circuits with arbitrary local noise using Pauli Propagation},
  author = {Armando Angrisani and Antonio A. Mele and Manuel S. Rudolph and M. Cerezo and Zoë Holmes},
  journal= {arXiv preprint arXiv:2501.13101},
  year   = {2026}
}

Comments

51 pages, 6 figures

R2 v1 2026-06-28T21:13:58.595Z