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A volumetric framework for quantum computer benchmarks

Quantum Physics 2020-11-17 v4

Abstract

We propose a very large family of benchmarks for probing the performance of quantum computers. We call them volumetric benchmarks (VBs) because they generalize IBM's benchmark for measuring quantum volume \cite{Cross18}. The quantum volume benchmark defines a family of square circuits whose depth dd and width ww are the same. A volumetric benchmark defines a family of rectangular quantum circuits, for which dd and ww are uncoupled to allow the study of time/space performance trade-offs. Each VB defines a mapping from circuit shapes -- (w,d)(w,d) pairs -- to test suites C(w,d)\mathcal{C}(w,d). A test suite is an ensemble of test circuits that share a common structure. The test suite C\mathcal{C} for a given circuit shape may be a single circuit CC, a specific list of circuits {C1CN}\{C_1\ldots C_N\} that must all be run, or a large set of possible circuits equipped with a distribution Pr(C)Pr(C). The circuits in a given VB share a structure, which is limited only by designers' creativity. We list some known benchmarks, and other circuit families, that fit into the VB framework: several families of random circuits, periodic circuits, and algorithm-inspired circuits. The last ingredient defining a benchmark is a success criterion that defines when a processor is judged to have "passed" a given test circuit. We discuss several options. Benchmark data can be analyzed in many ways to extract many properties, but we propose a simple, universal graphical summary of results that illustrates the Pareto frontier of the dd vs ww trade-off for the processor being benchmarked. [1] A. Cross, et al., Phys. Rev. A, 100, 032328, September 2019.

Keywords

Cite

@article{arxiv.1904.05546,
  title  = {A volumetric framework for quantum computer benchmarks},
  author = {Robin Blume-Kohout and Kevin C. Young},
  journal= {arXiv preprint arXiv:1904.05546},
  year   = {2020}
}

Comments

Latest version published in Quantum. 16 pages, 6 figures

R2 v1 2026-06-23T08:36:24.482Z