Francesco Albarelli scite author profile

We develop a resource theory for continuous-variable systems grounded on operations routinely available within current quantum technologies. In particular, the set of free operations is convex and includes quadratic transformations and conditional coarse-grained measurements. The present theory lends itself to quantify both quantum non-Gaussianity and Wigner negativity as resources, depending on the choice of the free-state seti.e., the convex hull of Gaussian states or the states with positive Wigner function, respectively. After showing that the theory admits no maximally resourceful state, we define a computable resource monotone -the Wigner logarithmic negativity. We use the latter to assess the resource content of experimentally relevant states -e.g., photon-added, photon-subtracted, cubic-phase, and cat states -and to find optimal working points of some resource concentration protocols. We envisage applications of this framework to sub-universal and universal quantum information processing over continuous variables. * francesco.albarelli@unimi.it † marco.genoni@fisica.unimi.it ‡ matteo.paris@fisica.unimi.it § a.ferraro@qub.ac.uk arXiv:1804.05763v2 [quant-ph] 4 Dec 2018 1. M(ρ) = 0 ∀ρ ∈ G (resp. W + ).

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A perspective on multiparameter quantum metrology: From theoretical tools to applications in quantum imaging

Albarelli

et al. 2020

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The interest in a system often resides in the interplay among different parameters governing its evolution. It is thus often required to access many of them at once for a complete description. Assessing how quantum enhancement in such multiparameter estimation can be achieved depends on understanding the many subtleties that come into play: establishing solid foundations is key to delivering future technology for this task. In this article we discuss the state of the art of quantum multiparameter estimation, with a particular emphasis on its theoretical tools, on application to imaging problems, and on the possible avenues towards the next developments.

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Evaluating the Holevo Cramér-Rao Bound for Multiparameter Quantum Metrology

2019

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Only with the simultaneous estimation of multiple parameters are the quantum aspects of metrology fully revealed. This is due to the incompatibility of observables. The fundamental bound for multi-parameter quantum estimation is the Holevo Cramér-Rao bound (HCRB) whose evaluation has so far remained elusive. For finitedimensional systems we recast its evaluation as a semidefinite program, with reduced size for rank-deficient states. We use this result to study phase and loss estimation in optical interferometry and three-dimensional magnetometry with noisy multi-qubit systems. For the former, we show that, in some regimes, it is possible to attain the HCRB with the optimal (single-copy) measurement for phase estimation. For the latter, we show a non-trivial interplay between the HCRB and incompatibility, and provide numerical evidence that projective single-copy measurements attain the HCRB in the noiseless two-qubit case.quantifies the precision of the estimation. The probability of observing the outcome ω is given by the Born arXiv:1906.05724v1 [quant-ph]

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