Precision Bounds for Characterising Quantum Measurements
Abstract
Quantum measurements, alongside quantum states and processes, form a cornerstone of quantum information processing. However, unlike states and processes, their efficient characterisation remains relatively unexplored. We resolve this asymmetry by introducing a comprehensive framework for efficient detector estimation that reveals the fundamental limits to extractable parameter information and errors arising in detector analysis - the detector quantum Fisher information. Our development eliminates the need to optimise for the best probe state, while highlighting aspects of detector analysis that fundamentally differ from quantum state estimation. Through proofs, examples and experimental validation, we demonstrate the relevance and robustness of our proposal for current quantum detector technologies. By formalising a dual perspective to state estimation, our framework completes and connects the triad of efficient state, process, and detector tomography, advancing quantum information theory with broader implications for emerging technologies reliant on precisely calibrated measurements.
Cite
@article{arxiv.2512.20091,
title = {Precision Bounds for Characterising Quantum Measurements},
author = {Aritra Das and Simon K. Yung and Lorcan O. Conlon and Ozlem Erkilic and Angus Walsh and Yong-Su Kim and Ping K. Lam and Syed M. Assad and Jie Zhao},
journal= {arXiv preprint arXiv:2512.20091},
year = {2026}
}
Comments
Published in Nat. Commun. (2026), presented at AIP (2025); 9 + 4 + 30 pages (main + methods + supplemental), 4 + 11 figures (main + supplemental)