Incompatibility robustness of quantum measurements: a unified framework

Abstract: In quantum mechanics performing a measurement is an invasive process which generally disturbs the system. Due to this phenomenon, there exist incompatible quantum measurements, i.e. measurements that cannot be simultaneously performed on a single copy of the system. It is then natural to ask what the most incompatible quantum measurements are. To answer this question, several measures have been proposed to quantify how incompatible a set of measurements is, however their properties are not well-understood. In … Show more

“…In writing the decompositions (32) we have decided to have the maximum possible value for the visibility h l q , , without imposing conditions on the class of allowed noises. As we remarked above, the last class of noises discussed in [32] is indeed the one of general POVMs. If the class of noises is restricted, the value of the visibility could diminish, as we can see in the example of = s 1 2, section 2.3.1.…”

“…A different approach [9,10,30,29,31,32] to the construction of compatible observables is to consider noisy versions of the target observables.…”

“…where p j is a classical probability, independent of the system state [9,30,31]. A review of some choices for the noise classes introduced in the literature is given in [32]; the typical choices are: (a) classical noises, (b) noises represented by compatible POVMs, (c) general POVMs.…”

“…Our aim in introducing the device information loss (46) and the minimum information loss (54), (55) was to have uncertainty measures, based on information theory, by which MURs could be expressed in a simple way, section 3.3; this construction produced also an incompatibility measure, the minimum information loss. The result above gives a link with the robustness measures [9,10,[29][30][31][32] which quantify the incompatibility by maximizing the visibility; in other terms, these measures are based on the ability of the target observables to maintain incompatibility against noise.…”

“…The visibilities above have been obtained by allowing for general noises, not only classical ones. Inside the noise robustness approach to incompatibility, the two visibilities h 1 2 r for spin 1/2 have already been obtained in [32]; they are in the class called incompatibility generalized robustness, which means that general POVMs are allowed for noises. By comparing with section 3.4, we can say that we have shown how to generalize this approach to the case of infinitely many observables, such as the spin vector.…”

Entropic measurement uncertainty relations for all the infinite components of a spin vector

“…In writing the decompositions (32) we have decided to have the maximum possible value for the visibility h l q , , without imposing conditions on the class of allowed noises. As we remarked above, the last class of noises discussed in [32] is indeed the one of general POVMs. If the class of noises is restricted, the value of the visibility could diminish, as we can see in the example of = s 1 2, section 2.3.1.…”

“…A different approach [9,10,30,29,31,32] to the construction of compatible observables is to consider noisy versions of the target observables.…”

“…where p j is a classical probability, independent of the system state [9,30,31]. A review of some choices for the noise classes introduced in the literature is given in [32]; the typical choices are: (a) classical noises, (b) noises represented by compatible POVMs, (c) general POVMs.…”

“…Our aim in introducing the device information loss (46) and the minimum information loss (54), (55) was to have uncertainty measures, based on information theory, by which MURs could be expressed in a simple way, section 3.3; this construction produced also an incompatibility measure, the minimum information loss. The result above gives a link with the robustness measures [9,10,[29][30][31][32] which quantify the incompatibility by maximizing the visibility; in other terms, these measures are based on the ability of the target observables to maintain incompatibility against noise.…”

“…The visibilities above have been obtained by allowing for general noises, not only classical ones. Inside the noise robustness approach to incompatibility, the two visibilities h 1 2 r for spin 1/2 have already been obtained in [32]; they are in the class called incompatibility generalized robustness, which means that general POVMs are allowed for noises. By comparing with section 3.4, we can say that we have shown how to generalize this approach to the case of infinitely many observables, such as the spin vector.…”

Entropic measurement uncertainty relations for all the infinite components of a spin vector

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