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Divide-and-conquer verification method for noisy intermediate-scale quantum computation

Quantum Physics 2022-07-13 v3

Abstract

Several noisy intermediate-scale quantum computations can be regarded as logarithmic-depth quantum circuits on a sparse quantum computing chip, where two-qubit gates can be directly applied on only some pairs of qubits. In this paper, we propose a method to efficiently verify such noisy intermediate-scale quantum computation. To this end, we first characterize small-scale quantum operations with respect to the diamond norm. Then by using these characterized quantum operations, we estimate the fidelity ψtρ^outψt\langle\psi_t|\hat{\rho}_{\rm out}|\psi_t\rangle between an actual nn-qubit output state ρ^out\hat{\rho}_{\rm out} obtained from the noisy intermediate-scale quantum computation and the ideal output state (i.e., the target state) ψt|\psi_t\rangle. Although the direct fidelity estimation method requires O(2n)O(2^n) copies of ρ^out\hat{\rho}_{\rm out} on average, our method requires only O(D3212D)O(D^32^{12D}) copies even in the worst case, where DD is the denseness of ψt|\psi_t\rangle. For logarithmic-depth quantum circuits on a sparse chip, DD is at most O(logn)O(\log{n}), and thus O(D3212D)O(D^32^{12D}) is a polynomial in nn. By using the IBM Manila 5-qubit chip, we also perform a proof-of-principle experiment to observe the practical performance of our method.

Keywords

Cite

@article{arxiv.2109.14928,
  title  = {Divide-and-conquer verification method for noisy intermediate-scale quantum computation},
  author = {Yuki Takeuchi and Yasuhiro Takahashi and Tomoyuki Morimae and Seiichiro Tani},
  journal= {arXiv preprint arXiv:2109.14928},
  year   = {2022}
}

Comments

17 pages, 7 figures, v3: Added a proof-of-principle experiment (Sec. IV) and improved Sec. V, Accepted for publication in Quantum

R2 v1 2026-06-24T06:30:40.195Z