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Computationally Efficient Quantum Expectation with Extended Bell Measurements

Quantum Physics 2022-04-20 v2

Abstract

Evaluating an expectation value of an arbitrary observable AC2n×2nA\in{\mathbb C}^{2^n\times 2^n} through na\"ive Pauli measurements requires a large number of terms to be evaluated. We approach this issue using a method based on Bell measurement, which we refer to as the extended Bell measurement method. This analytical method quickly assembles the 4n4^n matrix elements into at most 2n+12^{n+1} groups for simultaneous measurements in O(nd)O(nd) time, where dd is the number of non-zero elements of AA. The number of groups is particularly small when AA is a band matrix. When the bandwidth of AA is k=O(nc)k=O(n^c), the number of groups for simultaneous measurement reduces to O(nc+1)O(n^{c+1}). In addition, when non-zero elements densely fill the band, the variance is O((nc+1/2n)tr(A2))O((n^{c+1}/2^n)\,{\rm tr}(A^2)), which is small compared with the variances of existing methods. The proposed method requires a few additional gates for each measurement, namely one Hadamard gate, one phase gate and at most n1n-1 CNOT gates. Experimental results on an IBM-Q system show the computational efficiency and scalability of the proposed scheme, compared with existing state-of-the-art approaches. Code is available at https://github.com/ToyotaCRDL/extended-bell-measurements.

Keywords

Cite

@article{arxiv.2110.09735,
  title  = {Computationally Efficient Quantum Expectation with Extended Bell Measurements},
  author = {Ruho Kondo and Yuki Sato and Satoshi Koide and Seiji Kajita and Hideki Takamatsu},
  journal= {arXiv preprint arXiv:2110.09735},
  year   = {2022}
}

Comments

33 pages, 12 figures; most of the details of section 2 have been moved to the Appendix; added variance analysis and comparison with the classical shadow; code is available at https://github.com/ToyotaCRDL/extended-bell-measurements

R2 v1 2026-06-24T06:59:47.059Z