Quantum (Nov 2020)

Operational, gauge-free quantum tomography

  • Olivia Di Matteo,
  • John Gamble,
  • Chris Granade,
  • Kenneth Rudinger,
  • Nathan Wiebe

DOI
https://doi.org/10.22331/q-2020-11-17-364
Journal volume & issue
Vol. 4
p. 364

Abstract

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As increasingly impressive quantum information processors are realized in laboratories around the world, robust and reliable characterization of these devices is now more urgent than ever. These diagnostics can take many forms, but one of the most popular categories is $\textit{tomography}$, where an underlying parameterized model is proposed for a device and inferred by experiments. Here, we introduce and implement efficient operational tomography, which uses experimental observables as these model parameters. This addresses a problem of ambiguity in representation that arises in current tomographic approaches (the $\textit{gauge problem}$). Solving the gauge problem enables us to efficiently implement operational tomography in a Bayesian framework computationally, and hence gives us a natural way to include prior information and discuss uncertainty in fit parameters. We demonstrate this new tomography in a variety of different experimentally-relevant scenarios, including standard process tomography, Ramsey interferometry, randomized benchmarking, and gate set tomography.