We present a N-dimensional quantization a la Berezin-Klauder or frame
quantization of the complex plane based on overcomplete families of states
(coherent states) generated by the N first harmonic oscillator eigenstates. The
spectra of position and momentum operators are finite and eigenvalues are
equal, up to a factor, to the zeros of Hermite polynomials. From numerical and
theoretical studies of the large $N$ behavior of the product $\lambda\_m(N)
\lambda\_M(N)$ of non null smallest positive and largest eigenvalues, we infer
the inequality $\delta\_N(Q) \Delta\_N(Q) = \sigma\_N \overset{<}{\underset{N
\to \infty}{\to}} 2 \pi$ (resp. $\delta\_N(P) \Delta\_N(P) = \sigma\_N
\overset{<}{\underset{N \to \infty}{\to}} 2 \pi $) involving, in suitable
units, the minimal ($\delta\_N(Q)$) and maximal ($\Delta\_N(Q)$) sizes of
regions of space (resp. momentum) which are accessible to exploration within
this finite-dimensional quantum framework. Interesting issues on the
measurement process and connections with the finite Chern-Simons matrix model
for the Quantum Hall effect are discussed

Abramowitz M.

FRANCOIS-XAVIER MICHAUX

JEAN-PIERRE GAZEAU

Kuang L. M.

Lubinsky D. S.

PASCAL MONCEAU

Polychronakos A. P.

Press W. H.

English

arXiv

International audienceWe present a N-dimensional quantization a la Berezin-Klauder or frame quantization of the complex plane based on overcomplete families of states (coherent states) generated by the N first harmonic oscillator eigenstates. The spectra of position and momentum operators are finite and eigenvalues are equal, up to a factor, to the zeros of Hermite polynomials. From numerical and theoretical studies of the large $N$ behavior of the product $\lambda_m(N) \lambda_M(N)$ of non null smallest positive and largest eigenvalues, we infer the inequality $\delta_N(Q) \Delta_N(Q) = \sigma_N \overset{<}{\underset{N \to \infty}{\to}} 2 \pi$ (resp. $\delta_N(P) \Delta_N(P) = \sigma_N \overset{<}{\underset{N \to \infty}{\to}} 2 \pi $) involving, in suitable units, the minimal ($\delta_N(Q)$) and maximal ($\Delta_N(Q)$) sizes of regions of space (resp. momentum) which are accessible to exploration within this finite-dimensional quantum framework. Interesting issues on the measurement process and connections with the finite Chern-Simons matrix model for the Quantum Hall effect are discussed

Gazeau, Jean-Pierre

Josse-Michaux, François-Xavier

Monceau, Pascal

HAL-IN2P3

Finite dimensional quantizations of the (q,p) plane : new space and momentum inequalities

HAL-OBSPM

HAL: Hyper Article en Ligne

HAL-CEA

We present a N-dimensional quantization a la Berezin-Klauder or frame quantization of the complex plane based on overcomplete families of states (coherent states) generated by the N first harmonic oscillator eigenstates. The spectra of position and momentum operators are finite and eigenvalues are equal, up to a factor, to the zeros of Hermite polynomials. From numerical and theoretical studies of the large $N$ behavior of the product $\lambda_m(N) \lambda_M(N)$ of non null smallest positive and largest eigenvalues, we infer the inequality $\delta_N(Q) \Delta_N(Q) = \sigma_N \overset{<}{\underset{N \to \infty}{\to}} 2 \pi$ (resp. $\delta_N(P) \Delta_N(P) = \sigma_N \overset{<}{\underset{N \to \infty}{\to}} 2 \pi $) involving, in suitable units, the minimal ($\delta_N(Q)$) and maximal ($\Delta_N(Q)$) sizes of regions of space (resp. momentum) which are accessible to exploration within this finite-dimensional quantum framework. Interesting issues on the measurement process and connections with the finite Chern-Simons matrix model for the Quantum Hall effect are discussed

Gazeau, J.-P.

Josse-Michaux, F.-X.

Hal-Diderot

Crossref

FINITE DIMENSIONAL QUANTIZATIONS OF THE (q,p) PLANE: NEW SPACE AND MOMENTUM (OR QUADRATURES) INEQUALITIES

https://hal.archives-ouvertes.fr/hal-00003426v2/document

Finite dimensional quantizations of the (q,p) plane : new space and
  momentum inequalities

Finite dimensional quantizations of the (q,p) plane : new space and momentum inequalities

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