Symplectic Polar Duality, Quantum Blobs, and Generalized Gaussians
Abstract
:1. Introduction
- In Theorem 1, we use the notion of “symplectic polar duality” to characterize the phase space ellipsoids that arise as covariance ellipsoids of a quantum state. This result is very much related to what is called in quantum physics “symplectic tomography” [2], since it gives global information by studying the local information obtained by considering the intersection of with a Lagrangian plane;
- Theorem 2: We prove that a centered phase space ellipsoid is a quantum blob (i.e., a symplectic ball with radius [3,4,5]) if and only if the polar dual of the projection of on the position space is the intersection of with the momentum space; this considerably strengthens a previous result obtained in [1];
- Theorem 3: It is an analytical version of Theorem 2, which we use to give a simple characterization of pure Gaussian states in terms of partial information on the covariance ellipsoid of a Gaussian state. This result is related to the so-called “Pauli problem”.
2. A Geometric Quantum Phase Space
2.1. Polar Duality and Quantum States
- (reflexivity) and (anti-monotonicity);
- For all :(scaling property). In particular for all , .
2.2. Symplectic Polar Duality
2.3. Polar Duality and the Symplectic Camel
- SC1
- Monotonicity: If , then ;
- SC2
- Conformality: For every , we have ;
- SC3
- Symplectic invariance: for every ;
- SC4
- Normalization: For , we have , where is the cylinder with radius r based on the plane.
- SC3lin Linear symplectic invariance: for every and for every .
3. Projections and Intersections of Quantum Blobs
3.1. Block Matrix Notation
3.2. Reconstruction of Quantum Blobs: Discussion
3.3. Intersections with Lagrangian Planes
4. Gaussian Quantum Phase Space
4.1. Generalized Gaussians and Their Wigner Transforms
- is the set of all centered Gaussian functions (57): if and only if there exists such that ;
- is the set of all centered quantum blobs: if and only if there exists , such that .
4.2. Gaussian Density Operators
4.3. A characterization of Gaussian Density Operators
5. Perspectives and Comments
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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de Gosson, M.; de Gosson, C. Symplectic Polar Duality, Quantum Blobs, and Generalized Gaussians. Symmetry 2022, 14, 1890. https://doi.org/10.3390/sym14091890
de Gosson M, de Gosson C. Symplectic Polar Duality, Quantum Blobs, and Generalized Gaussians. Symmetry. 2022; 14(9):1890. https://doi.org/10.3390/sym14091890
Chicago/Turabian Stylede Gosson, Maurice, and Charlyne de Gosson. 2022. "Symplectic Polar Duality, Quantum Blobs, and Generalized Gaussians" Symmetry 14, no. 9: 1890. https://doi.org/10.3390/sym14091890
APA Stylede Gosson, M., & de Gosson, C. (2022). Symplectic Polar Duality, Quantum Blobs, and Generalized Gaussians. Symmetry, 14(9), 1890. https://doi.org/10.3390/sym14091890