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Spoofing Linear Cross-Entropy Benchmarking in Shallow Quantum Circuits

Quantum Physics 2020-05-07 v1 Computational Complexity

Abstract

The linear cross-entropy benchmark (Linear XEB) has been used as a test for procedures simulating quantum circuits. Given a quantum circuit CC with nn inputs and outputs and purported simulator whose output is distributed according to a distribution pp over {0,1}n\{0,1\}^n, the linear XEB fidelity of the simulator is FC(p)=2nExpqC(x)1\mathcal{F}_{C}(p) = 2^n \mathbb{E}_{x \sim p} q_C(x) -1 where qC(x)q_C(x) is the probability that xx is output from the distribution C0nC|0^n\rangle. A trivial simulator (e.g., the uniform distribution) satisfies FC(p)=0\mathcal{F}_C(p)=0, while Google's noisy quantum simulation of a 53 qubit circuit CC achieved a fidelity value of (2.24±0.21)×103(2.24\pm0.21)\times10^{-3} (Arute et. al., Nature'19). In this work we give a classical randomized algorithm that for a given circuit CC of depth dd with Haar random 2-qubit gates achieves in expectation a fidelity value of Ω(nL15d)\Omega(\tfrac{n}{L} \cdot 15^{-d}) in running time poly(n,2L)\textsf{poly}(n,2^L). Here LL is the size of the \emph{light cone} of CC: the maximum number of input bits that each output bit depends on. In particular, we obtain a polynomial-time algorithm that achieves large fidelity of ω(1)\omega(1) for depth O(logn)O(\sqrt{\log n}) two-dimensional circuits. To our knowledge, this is the first such result for two dimensional circuits of super-constant depth. Our results can be considered as an evidence that fooling the linear XEB test might be easier than achieving a full simulation of the quantum circuit.

Keywords

Cite

@article{arxiv.2005.02421,
  title  = {Spoofing Linear Cross-Entropy Benchmarking in Shallow Quantum Circuits},
  author = {Boaz Barak and Chi-Ning Chou and Xun Gao},
  journal= {arXiv preprint arXiv:2005.02421},
  year   = {2020}
}
R2 v1 2026-06-23T15:20:01.994Z