Optimal filtering in fractional Fourier domains

Kutay, M. Alper; Özaktaş, Haldun M.; Ankan, Orhan; Onural, Levent

doi:10.1109/78.575688

Cited by 260 publications

(84 citation statements)

References 38 publications

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“…As fractional Fourier transform (FRFT) [3,4] is a generalization of the conventional Fourier transform and consists of spatial and frequency information, it is natural to extend its use in IR applications. Besides, the use of the FRFT is motivated by the observation in [5] that the optimum FRFT domain for noise elimination may be different from the conventional spatial or frequency domain.…”

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confidence: 99%

Image registration based on Fractional Fourier Transform

Niu

Chen

et al. 2015

Optik

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Section: Page 3 Of 16mentioning

confidence: 99%

Image registration based on Fractional Fourier Transform

Niu

Chen

et al. 2015

Optik

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“…However, these methodologies may not be extendable to any problem, either by its nature or because they do not provide satisfactory results. From this need, efforts have focused on the description of a theory allowing the signal processing in fractional domains [17][18][19][20]. All these initiatives aim to propose an alternative solution with the important feature of maintaining a harmonic description of the problem.…”

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confidence: 99%

A time-variant filtering approach for non-stationary random signals based on the fractional convolution

2016

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“…The fractional version of the optimal Wiener ®ltering problem has been studied in detail in Ref. [4]. Fractional Fourier-domain ®ltering has been further generalized to multi-stage and multi-channel ®ltering ( Fig.…”

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“…1(a)±(c)) [3,4]. Fractional Fourier-domain ®ltering consists of (i) taking the fractional Fourier transform of the input signal, (ii) multiplication with a ®lter function, and (iii) taking the inverse fractional Fourier transform of the result.…”

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Image representation and compression with the fractional Fourier transform

Yetik

Kutay

Özaktaş

2001

Optics Communications

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We discuss the application of fractional Fourier transform-based ®ltering con®gurations to image representation and compression. An image can be approximately represented (and stored or transmitted) as the coe cients of the minimum mean square ®ltering con®guration approximating the image matrix. An order of magnitude compression is possible with moderate errors with the raw method. While inferior to commonly available compression algorithms, the results presented correspond to the basic method without any re®nement or combination with other techniques, suggesting that the approach may hold promise for future development. Regardless of its practical usefulness, the fact that the information inherent in an image can be decomposed or factored into fractional Fourier domains is of considerable conceptual signi®cance. The information contained in the image is distributed to the di erent domains in an unequal way, making some domains more dispensible than others in representing the image. Ó 2001 Published by Elsevier Science B.V.

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Optimal filtering in fractional Fourier domains

Cited by 260 publications

References 38 publications

Image registration based on Fractional Fourier Transform

Image registration based on Fractional Fourier Transform

A time-variant filtering approach for non-stationary random signals based on the fractional convolution

Image representation and compression with the fractional Fourier transform

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