2018
DOI: 10.1016/j.matpur.2017.12.004
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Convolutions for localization operators

Abstract: Quantum harmonic analysis on phase space is shown to be linked with localization operators. The convolution between operators and the convolution between a function and an operator provide a conceptual framework for the theory of localization operators which is complemented by an appropriate Fourier transform, the Fourier-Wigner transform. We link the Hausdorff-Young inequality for the Fourier-Wigner transform with Lieb's inequality for ambiguity functions. Noncommutative Tauberian theorems due to Werner allow… Show more

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Cited by 46 publications
(86 citation statements)
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References 29 publications
(104 reference statements)
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“…The convolutions can be defined on other L p -spaces and Schatten p-classes by duality [27,36]. As a special case we mention that (4) defines a continuous function even when T ∈ B(L 2 (R d )) [27]; in particular it is clear from (4) that (5) S ⋆ I(z) = tr(S) for any z ∈ R 2d when I is the identity operator and S ∈ T .…”
Section: 3mentioning
confidence: 99%
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“…The convolutions can be defined on other L p -spaces and Schatten p-classes by duality [27,36]. As a special case we mention that (4) defines a continuous function even when T ∈ B(L 2 (R d )) [27]; in particular it is clear from (4) that (5) S ⋆ I(z) = tr(S) for any z ∈ R 2d when I is the identity operator and S ∈ T .…”
Section: 3mentioning
confidence: 99%
“…The convolutions can be defined on other L p -spaces and Schatten p-classes by duality [27,36]. As a special case we mention that (4) defines a continuous function even when T ∈ B(L 2 (R d )) [27]; in particular it is clear from (4) that (5) S ⋆ I(z) = tr(S) for any z ∈ R 2d when I is the identity operator and S ∈ T . The convolutions of operators and functions are associative, a fact that is non-trivial since the convolutions between operators and functions can produce both operators and functions as output [27,36].…”
Section: 3mentioning
confidence: 99%
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“…Note that the Fourier-Wigner transform and the spreading function differ only by a phase factor. The Fourier-Wigner transform has many properties analogous to those of the Fourier transform of functions [55,66]. In the case of rank-one operators these concepts of quantum harmonic analysis turn into wellknown objects from time-frequency analysis.…”
mentioning
confidence: 99%
“…The Fourier-Wigner transform of a rank-one operator is the ambiguity function. There is also a Hausdorff-Young inequality associated to the Fourier-Wigner transform [55,66], that in the rank-one case is the non-sharp Lieb's inequality for ambiguity functions [51]. Let us return to the objectives of this paper.…”
mentioning
confidence: 99%