Coherent states and theta functions

A. M. Perelomov

doi:10.1007/bf01077648

Calculation of the Riesz constants and orthogonalization for incomplete systems of coherent states by means of theta functions

Sbornik Mathematics ◽

10.1070/sm8542 ◽

2016 ◽

Vol 207 (8) ◽

pp. 1127-1141

Author(s):

E A Kiselev ◽

L A Minin ◽

I Ya Novikov

Keyword(s):

Coherent States ◽

Theta Functions ◽

Incomplete Systems

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Fermionic coherent states

Introduction to Quantum Fields on a Lattice ◽

10.1017/cbo9780511583971.012 ◽

2002 ◽

pp. 242-252

Keyword(s):

Coherent States

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Gazeau- Klouder Coherent states on a sphere

Iranian Journal of Physics Research ◽

10.29252/ijpr.19.2.379 ◽

2019 ◽

Vol 19 (2) ◽

pp. 379-390

Author(s):

Z Heibati ◽

A Mahdifar ◽

E Amooghorban ◽

◽

...

Keyword(s):

Coherent States

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Semi-Classical Localisation Properties of Quantum Oscillators on a Noncommutative Configuration Space

Open Systems & Information Dynamics ◽

10.1142/s1230161215500213 ◽

2015 ◽

Vol 22 (04) ◽

pp. 1550021 ◽

Cited By ~ 1

Author(s):

Fabio Benatti ◽

Laure Gouba

Keyword(s):

Phase Space ◽

Configuration Space ◽

Classical Limit ◽

Coherent States ◽

Point Of View ◽

Quantum Mechanical ◽

Wigner Functions ◽

Quantum Mechanical Oscillators ◽

Mechanical Oscillators ◽

Space Noncommutativity

When dealing with the classical limit of two quantum mechanical oscillators on a noncommutative configuration space, the limits corresponding to the removal of configuration-space noncommutativity and position-momentum noncommutativity do not commute. We address this behaviour from the point of view of the phase-space localisation properties of the Wigner functions of coherent states under the two limits.

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Joseph Fourier 250thBirthday: Modern Fourier Analysis and Fourier Heat Equation in Information Sciences for the XXIst Century

Entropy ◽

10.3390/e21030250 ◽

2019 ◽

Vol 21 (3) ◽

pp. 250

Author(s):

Frédéric Barbaresco ◽

Jean-Pierre Gazeau

Keyword(s):

Fourier Analysis ◽

Heat Equation ◽

Harmonic Analysis ◽

Lie Groups ◽

Coherent States ◽

Geometric Theory ◽

Plancherel Formula ◽

Group Representations ◽

Modern Development ◽

Xxist Century

For the 250th birthday of Joseph Fourier, born in 1768 at Auxerre in France, this MDPI special issue will explore modern topics related to Fourier analysis and Fourier Heat Equation. Fourier analysis, named after Joseph Fourier, addresses classically commutative harmonic analysis. The modern development of Fourier analysis during XXth century has explored the generalization of Fourier and Fourier-Plancherel formula for non-commutative harmonic analysis, applied to locally compact non-Abelian groups. In parallel, the theory of coherent states and wavelets has been generalized over Lie groups (by associating coherent states to group representations that are square integrable over a homogeneous space). The name of Joseph Fourier is also inseparable from the study of mathematics of heat. Modern research on Heat equation explores geometric extension of classical diffusion equation on Riemannian, sub-Riemannian manifolds, and Lie groups. The heat equation for a general volume form that not necessarily coincides with the Riemannian one is useful in sub-Riemannian geometry, where a canonical volume only exists in certain cases. A new geometric theory of heat is emerging by applying geometric mechanics tools extended for statistical mechanics, for example, the Lie groups thermodynamics.

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2 Jacobi’s theta functions of one variable and the triple product identity

Theta functions, elliptic functions and π ◽

10.1515/9783110541915-002 ◽

2020 ◽

pp. 15-28

Keyword(s):

Theta Functions ◽

Triple Product ◽

Product Identity

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Second-order integrable Lagrangians and WDVV equations

Letters in Mathematical Physics ◽

10.1007/s11005-021-01403-3 ◽

2021 ◽

Vol 111 (2) ◽

Author(s):

E. V. Ferapontov ◽

M. V. Pavlov ◽

Lingling Xue

Keyword(s):

Lagrangian Density ◽

Theta Functions ◽

Second Order ◽

Elementary Functions ◽

Lagrange Equations ◽

Wdvv Equations ◽

Integrability Conditions ◽

Jacobi Theta Functions

AbstractWe investigate the integrability of Euler–Lagrange equations associated with 2D second-order Lagrangians of the form $$\begin{aligned} \int f(u_{xx},u_{xy},u_{yy})\ \mathrm{d}x\mathrm{d}y. \end{aligned}$$ ∫ f ( u xx , u xy , u yy ) d x d y . By deriving integrability conditions for the Lagrangian density f, examples of integrable Lagrangians expressible via elementary functions, Jacobi theta functions and dilogarithms are constructed. A link of second-order integrable Lagrangians to WDVV equations is established. Generalisations to 3D second-order integrable Lagrangians are also discussed.

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Higher depth mock theta functions and q-hypergeometric series

Forum Mathematicum ◽

10.1515/forum-2021-0013 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Joshua Males ◽

Andreas Mono ◽

Larry Rolen

Keyword(s):

Theta Function ◽

Modular Forms ◽

Hypergeometric Series ◽

Theta Functions ◽

Mock Theta Function ◽

Mock Theta Functions ◽

Maass Forms ◽

Mock Modular Forms ◽

Harmonic Maass Forms

Abstract In the theory of harmonic Maaß forms and mock modular forms, mock theta functions are distinguished examples which arose from q-hypergeometric examples of Ramanujan. Recently, there has been a body of work on higher depth mock modular forms. Here, we introduce distinguished examples of these forms, which we call higher depth mock theta functions, and develop q-hypergeometric expressions for them. We provide three examples of mock theta functions of depth two, each arising by multiplying a classical mock theta function with a certain specialization of a universal mock theta function. In addition, we give their modular completions, and relate each to a q-hypergeometric series.

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