Some uncertainty principles for time-frequency transforms of the Cohen class

Windowing a Fourier transform is a useful tool, which gives us the similarity between the signal and time frequency signal, and it allows to get sense when/where certain frequencies occur in the input signal, this method was introduced by Dennis Gabor. In this paper, we generalize the classical Gabor–Fourier transform (GFT) to the Riemannian symmetric space calling it the Helgason–Gabor–Fourier transform (HGFT). We prove several important properties of HGFT like the reconstruction formula, the Plancherel formula and Parseval formula. Finally, we establish some local uncertainty principle such as Benedicks-type uncertainty principle.

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Pseudo Cohen Time-Frequency Distributions in Infinite Variance Noise Environment

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.475-476.253 ◽

2013 ◽

Vol 475-476 ◽

pp. 253-258

Author(s):

Hai Bin Wang ◽

Jun Bo Long ◽

Dai Feng Zha

Keyword(s):

Order Statistic ◽

Stable Distribution ◽

Impulsive Noise ◽

Infinite Variance ◽

Frequency Distributions ◽

Time Frequency ◽

Noise Environment ◽

Class Distribution ◽

Cohen Class ◽

Low Order

stable distribution has been suggested as a more appropriate model in impulsive noise environment.The performance of conventional time-frequency distributions (TFDs) degenerate in stable distribution noise environment. Hence, three improved methods are proposed based on Fractional Low Order statistics, Fractional Low Order Wigner-Ville Distribution (FLO-WVD), Fractional Low Order Statistic pseudo Wigner-Ville Distribution (FLO-PWVD), Fractional Low Order Statistic Cohen class distribution (FLO-Cohen). In order for real-time, on-line operation and fairly long signals processing, a new smoothed pseudo Fractional Low Order Cohen class distribution (PFLO-Cohen) is proposed.Simulations show that the methods demonstrate the advantages in this paper, are robust.

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Enhanced Cohen class time–frequency methods based on a structure tensor analysis: Applications to ISAR processing

Signal Processing ◽

10.1016/j.sigpro.2012.12.016 ◽

2013 ◽

Vol 93 (7) ◽

pp. 1813-1830 ◽

Cited By ~ 6

Author(s):

Vincent Corretja ◽

Eric Grivel ◽

Yannick Berthoumieu ◽

Jean-Michel Quellec ◽

Thierry Sfez ◽

...

Keyword(s):

Structure Tensor ◽

Tensor Analysis ◽

Time Frequency ◽

Class Time ◽

Cohen Class

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Effect of fractional Fourier transformation on time-frequency distributions belonging to the Cohen class

IEEE Signal Processing Letters ◽

10.1109/97.484211 ◽

1996 ◽

Vol 3 (2) ◽

pp. 40-41 ◽

Cited By ~ 40

Author(s):

H.M. Ozaktas ◽

N. Erkaya ◽

M.A. Kutay

Keyword(s):

Fourier Transformation ◽

Frequency Distributions ◽

Time Frequency ◽

Cohen Class

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Global and local uncertainty principles for signals on graphs

APSIPA Transactions on Signal and Information Processing ◽

10.1017/atsip.2018.2 ◽

2018 ◽

Vol 7 ◽

Cited By ~ 7

Author(s):

Nathanael Perraudin ◽

Benjamin Ricaud ◽

David I Shuman ◽

Pierre Vandergheynst

Keyword(s):

Local Structure ◽

Small Region ◽

Uncertainty Principles ◽

Missing Information ◽

Spectral Filter ◽

Time Frequency ◽

Local Uncertainty ◽

Linear Signal ◽

Global And Local ◽

Global Uncertainty

Uncertainty principles such as Heisenberg's provide limits on the time-frequency concentration of a signal, and constitute an important theoretical tool for designing linear signal transforms. Generalizations of such principles to the graph setting can inform dictionary design, lead to algorithms for reconstructing missing information via sparse representations, and yield new graph analysis tools. While previous work has focused on generalizing notions of spreads of graph signals in the vertex and graph spectral domains, our approach generalizes the methods of Lieb in order to develop uncertainty principles that provide limits on the concentration of the analysis coefficients of any graph signal under a dictionary transform. One challenge we highlight is that the local structure in a small region of an inhomogeneous graph can drastically affect the uncertainty bounds, limiting the information provided by global uncertainty principles. Accordingly, we suggest new notions of locality, and develop local uncertainty principles that bound the concentration of the analysis coefficients of each atom of a localized graph spectral filter frame in terms of quantities that depend on the local structure of the graph around the atom's center vertex. Finally, we demonstrate how our proposed local uncertainty measures can improve the random sampling of graph signals.

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