Coherent States of Parametric Oscillators in the Probability Representation of Quantum Mechanics†

In this paper, we study coherent states for a quantum Pauli model through supersymmetric quantum mechanics (SUSYQM) method. From the point of view of canonical quantization, the construction of these coherent states is based on the very important differential operators in SUSYQM call factorization operators. The connection between classical and quantum theory is given by using the geometric properties of these states.

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Even and odd coherent states and tomographic representation of quantum mechanics and quantum optics VI. Man'ko

Theory of Nonclassical States of Light ◽

10.1201/9781482288223-9 ◽

2003 ◽

pp. 231-252

Keyword(s):

Quantum Mechanics ◽

Quantum Optics ◽

Coherent States ◽

Tomographic Representation

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Coherent states for the quantum mechanics on a torus

Physical Review A ◽

10.1103/physreva.75.052102 ◽

2007 ◽

Vol 75 (5) ◽

Cited By ~ 11

Author(s):

K. Kowalski ◽

J. Rembieliński

Keyword(s):

Quantum Mechanics ◽

Coherent States

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COHERENT STATES IN PARASUPERSYMMETRIC QUANTUM MECHANICS

Modern Physics Letters A ◽

10.1142/s0217732389002574 ◽

1989 ◽

Vol 04 (23) ◽

pp. 2289-2293 ◽

Cited By ~ 10

Author(s):

J. BECKERS ◽

N. DEBERGH

Keyword(s):

Quantum Mechanics ◽

Coherent States ◽

Annihilation Operator

New parasupersymmetric coherent states are determined as eigenstates of an annihilation operator. They are the closest parasupersymmetric states to the classical ones.

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New System-Specific Coherent States by Supersymmetric Quantum Mechanics for Bound State Calculations

Advances in Quantum Mechanics ◽

10.5772/54010 ◽

2013 ◽

Author(s):

Chia-Chun Chou ◽

Mason T. ◽

Bernhard G. ◽

Donald J.

Keyword(s):

Quantum Mechanics ◽

Coherent States ◽

Bound State ◽

Supersymmetric Quantum Mechanics ◽

New System

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Coherent States Formulation of Quantum Mechanics

Nonequilibrium Quantum Transport Physics in Nanosystems ◽

10.1142/9789812835376_0007 ◽

2009 ◽

pp. 68-81

Keyword(s):

Quantum Mechanics ◽

Coherent States

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p-adic quantum mechanics and coherent states 2. Oscillator eigenfunctions

Theoretical and Mathematical Physics ◽

10.1007/bf01028423 ◽

1991 ◽

Vol 86 (3) ◽

pp. 258-265 ◽

Cited By ~ 4

Author(s):

E. I. Zelenov

Keyword(s):

Quantum Mechanics ◽

Coherent States

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MAGNETIC GROUP ON THE PSEUDOSPHERE

International Journal of Modern Physics B ◽

10.1142/s0217979292001559 ◽

1992 ◽

Vol 06 (21) ◽

pp. 3525-3537 ◽

Cited By ~ 3

Author(s):

V. BARONE ◽

V. PENNA ◽

P. SODANO

Keyword(s):

Magnetic Field ◽

Hilbert Space ◽

Quantum Mechanics ◽

Constant Magnetic Field ◽

Coherent States ◽

Compact Operators ◽

Point Of View ◽

Algebraic Point ◽

Planar Limit ◽

Discrete Part

The quantum mechanics of a particle moving on a pseudosphere under the action of a constant magnetic field is studied from an algebraic point of view. The magnetic group on the pseudosphere is SU(1, 1). The Hilbert space for the discrete part of the spectrum is investigated. The eigenstates of the non-compact operators (the hyperbolic magnetic translators) are constructed and shown to be expressible as continuous superpositions of coherent states. The planar limit of both the algebra and the eigenstates is analyzed. Some possible applications are briefly outlined.

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Superposition Principle and Born’s Rule in the Probability Representation of Quantum States

Quantum Reports ◽

10.3390/quantum1020013 ◽

2019 ◽

Vol 1 (2) ◽

pp. 130-150 ◽

Cited By ~ 7

Author(s):

Igor Ya. Doskoch ◽

Margarita A. Man’ko

Keyword(s):

Quantum Mechanics ◽

Probability Distribution ◽

Particle System ◽

Superposition Principle ◽

Quantum States ◽

Particle State ◽

Probability Representation ◽

Tomographic Probability ◽

Born’S Rule ◽

System States

The basic notion of physical system states is different in classical statistical mechanics and in quantum mechanics. In classical mechanics, the particle system state is determined by its position and momentum; in the case of fluctuations, due to the motion in environment, it is determined by the probability density in the particle phase space. In quantum mechanics, the particle state is determined either by the wave function (state vector in the Hilbert space) or by the density operator. Recently, the tomographic-probability representation of quantum states was proposed, where the quantum system states were identified with fair probability distributions (tomograms). In view of the probability-distribution formalism of quantum mechanics, we formulate the superposition principle of wave functions as interference of qubit states expressed in terms of the nonlinear addition rule for the probabilities identified with the states. Additionally, we formulate the probability given by Born’s rule in terms of symplectic tomographic probability distribution determining the photon states.

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