English

Practical, Reliable Error Bars in Quantum Tomography

Quantum Physics 2016-07-05 v2

Abstract

Precise characterization of quantum devices is usually achieved with quantum tomography. However, most methods which are currently widely used in experiments, such as maximum likelihood estimation, lack a well-justified error analysis. Promising recent methods based on confidence regions are difficult to apply in practice or yield error bars which are unnecessarily large. Here, we propose a practical yet robust method for obtaining error bars. We do so by introducing a novel representation of the output of the tomography procedure, the "quantum error bars". This representation is (i) concise, being given in terms of few parameters, (ii) intuitive, providing a fair idea of the "spread" of the error, and (iii) useful, containing the necessary information for constructing confidence regions. The statements resulting from our method are formulated in terms of a figure of merit, such as the fidelity to a reference state. We present an algorithm for computing this representation and provide ready-to-use software. Our procedure is applied to actual experimental data obtained from two superconducting qubits in an entangled state, demonstrating the applicability of our method.

Keywords

Cite

@article{arxiv.1509.06763,
  title  = {Practical, Reliable Error Bars in Quantum Tomography},
  author = {Philippe Faist and Renato Renner},
  journal= {arXiv preprint arXiv:1509.06763},
  year   = {2016}
}

Comments

Journal version; 4+13 pages, 3+6 figures, 1 table. The new version introduces the "quantum error bars". Software available at https://github.com/Tomographer/tomographer/

R2 v1 2026-06-22T11:03:05.820Z