Wigner entropy conjecture and the interference formula in quantum phase space
Wigner-positive quantum states have the peculiarity to admit a Wigner function that is a genuine probability distribution over phase space. The Shannon differential entropy of the Wigner function of such states - called Wigner entropy for brevity - emerges as a fundamental information-theoretic meas...
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| creator | Van Herstraeten, Zacharie Cerf, Nicolas J |
| description | Wigner-positive quantum states have the peculiarity to admit a Wigner
function that is a genuine probability distribution over phase space. The
Shannon differential entropy of the Wigner function of such states - called
Wigner entropy for brevity - emerges as a fundamental information-theoretic
measure in phase space and is subject to a conjectured lower bound, reflecting
the uncertainty principle. In this work, we prove that this Wigner entropy
conjecture holds true for a broad class of Wigner-positive states known as
beam-splitter states, which are obtained by evolving a separable state through
a balanced beam splitter and then discarding one mode. Our proof relies on
known bounds on the $p$-norms of cross-Wigner functions and on the interference
formula, which relates the convolution of Wigner functions to the squared
modulus of a cross-Wigner function. Originally discussed in the context of
signal analysis, the interference formula is not commonly used in quantum
optics although it unveils a strong symmetry exhibited by Wigner functions of
pure states. We provide here a simple proof of the formula and highlight some
of its implications. Finally, we prove an extended conjecture on the
Wigner-R\'enyi entropy of beam-splitter states, albeit in a restricted range
for the R\'enyi parameter $\alpha \geq 1/2$. |
| doi_str_mv | 10.48550/arxiv.2411.05562 |
| format | Article |
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function that is a genuine probability distribution over phase space. The
Shannon differential entropy of the Wigner function of such states - called
Wigner entropy for brevity - emerges as a fundamental information-theoretic
measure in phase space and is subject to a conjectured lower bound, reflecting
the uncertainty principle. In this work, we prove that this Wigner entropy
conjecture holds true for a broad class of Wigner-positive states known as
beam-splitter states, which are obtained by evolving a separable state through
a balanced beam splitter and then discarding one mode. Our proof relies on
known bounds on the $p$-norms of cross-Wigner functions and on the interference
formula, which relates the convolution of Wigner functions to the squared
modulus of a cross-Wigner function. Originally discussed in the context of
signal analysis, the interference formula is not commonly used in quantum
optics although it unveils a strong symmetry exhibited by Wigner functions of
pure states. We provide here a simple proof of the formula and highlight some
of its implications. Finally, we prove an extended conjecture on the
Wigner-R\'enyi entropy of beam-splitter states, albeit in a restricted range
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function that is a genuine probability distribution over phase space. The
Shannon differential entropy of the Wigner function of such states - called
Wigner entropy for brevity - emerges as a fundamental information-theoretic
measure in phase space and is subject to a conjectured lower bound, reflecting
the uncertainty principle. In this work, we prove that this Wigner entropy
conjecture holds true for a broad class of Wigner-positive states known as
beam-splitter states, which are obtained by evolving a separable state through
a balanced beam splitter and then discarding one mode. Our proof relies on
known bounds on the $p$-norms of cross-Wigner functions and on the interference
formula, which relates the convolution of Wigner functions to the squared
modulus of a cross-Wigner function. Originally discussed in the context of
signal analysis, the interference formula is not commonly used in quantum
optics although it unveils a strong symmetry exhibited by Wigner functions of
pure states. We provide here a simple proof of the formula and highlight some
of its implications. Finally, we prove an extended conjecture on the
Wigner-R\'enyi entropy of beam-splitter states, albeit in a restricted range
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function that is a genuine probability distribution over phase space. The
Shannon differential entropy of the Wigner function of such states - called
Wigner entropy for brevity - emerges as a fundamental information-theoretic
measure in phase space and is subject to a conjectured lower bound, reflecting
the uncertainty principle. In this work, we prove that this Wigner entropy
conjecture holds true for a broad class of Wigner-positive states known as
beam-splitter states, which are obtained by evolving a separable state through
a balanced beam splitter and then discarding one mode. Our proof relies on
known bounds on the $p$-norms of cross-Wigner functions and on the interference
formula, which relates the convolution of Wigner functions to the squared
modulus of a cross-Wigner function. Originally discussed in the context of
signal analysis, the interference formula is not commonly used in quantum
optics although it unveils a strong symmetry exhibited by Wigner functions of
pure states. We provide here a simple proof of the formula and highlight some
of its implications. Finally, we prove an extended conjecture on the
Wigner-R\'enyi entropy of beam-splitter states, albeit in a restricted range
for the R\'enyi parameter $\alpha \geq 1/2$.</abstract><doi>10.48550/arxiv.2411.05562</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Quantum Physics |
| title | Wigner entropy conjecture and the interference formula in quantum phase space |
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