Optimal positive-operator-valued measures for unambiguous state discrimination
Abstract
Optimization of the mean efficiency for unambiguous (or error free)discrimination among given linearly independent nonorthogonal states should be realized in a way to keep the probabilistic quantum mechanical interpretation. This imposes a condition on a certain matrix to be positive semidefinite. We reformulated this condition in such a way that the conditioned optimization problem for the mean efficiency was reduced to finding an unconditioned maximum of a function defined on a unit -sphere for equiprobable states and on an -ellipsoid if the states are given with different probabilities. We established that for equiprobable states a point on the sphere with equal values of Cartesian coordinates, which we call symmetric point, plays a special role. Sufficient conditions for a vector set are formulated for which the mean efficiency for equiprobable states takes its maximal value at the symmetric point. This set, in particular, includes previously studied symmetric states. A subset of symmetric states, for which the optimal measurement corresponds to a POVM requiring a one-dimensional ancilla space is constructed. We presented our constructions of a POVM suitable for the ancilla space dimension varying from 1 till and the Neumark's extension differing from the existing schemes by the property that it is straightforwardly applicable to the case when it is desirable to present the whole space system + ancilla as the tensor product of a two-dimensional ancilla space and the -dimensional system space.
Cite
@article{arxiv.0806.2699,
title = {Optimal positive-operator-valued measures for unambiguous state discrimination},
author = {Boris F. Samsonov},
journal= {arXiv preprint arXiv:0806.2699},
year = {2013}
}
Comments
Thanks to the referee the paper is essentially enlarged and corrected. To be published in Phys. Rev. A