Optimal Strategies in Post-Selected Quantum Metrology
ORAL
Abstract
Post-selected quantum metrology uses filters to allow detectors to operate at lower intensities without reducing the input rate of quantum information about unknown parameters of interest [1, 2, 3]. In this talk, I will present the optimal family of filters that achieves this lossless compression of information [4]. I will also show that optimal post-selection can always increase the (Fisher) information per output state, even in the presence of strong depolarising noise. This is true irrespectively of whether detector saturation or post-processing costs are dominant. Our optimal filter depends on the underlying parameters to be estimated. Thus, the best way to distil quantum information involves an adaptive strategy [5]. I will present our efforts towards constructing such an optimal adaptive strategy. Finally, I will explore potential applications of post-selection in metrology.
*Harding Foundation and the Cambridge Vice-Chancellor's Award
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Publication:[1] Lupu-Gladstein N. B., et al., Negative Quasiprobabilities Enhance Phase Estimation in Quantum-Optics Experiment, Phys. Rev. Lett. 128, 220504 (2022). [2] Jenne J. H., and Arvidsson-Shukur D.R.M., Unbounded and lossless compression of multiparameter quantum information, Phys. Rev. A 106, 042404 (2022). [3] Arvidsson-Shukur D.R.M., et al., Quantum advantage in postselected metrology, Nat. Commun. 11, 3775 (2020). [4] Salvati F., Salmon W., Barnes C.H.W., and Arvidsson-Shukur D.R.M., Compression of metrological quantum information in the presence of noise, arXiv:2307.08648 [quant-ph] (2023). [5] Arvidsson-Shukur D.R.M., et al., Nat Commun 11, 3775 (2020).
