Fractional convolution

David Mustard

doi:10.1017/S0334270000012509

Abstract

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A continuous one-parameter set of binary operators on L2(R) called fractional convolution operators and which includes those of multiplication and convolution as particular cases is constructed by means of the Condon-Bargmann fractional Fourier transform. A fractional convolution theorem generalizes the standard Fourier convolution theorems and a fractional unit distribution generalizes the unit and delta distributions. Some explicit double-integral formulas for the fractional convolution between two functions are given and the induced operation between their corresponding Wigner distributions is found.

References

[1]Bargmann, V., “On a Hilbert space of analytic functions and an associated integral transform. Part I” Comm. Pure Appl. Math. 14 (1961) 187–214.CrossRef Google Scholar

[2]Claasen, T. A. C. M. and Mecklenbräuker, W.F.G., “The Wigner distribution - a tool for time- frequency signal analysis III”, Philips J. Res. 35 (1980) 372–389.Google Scholar

[3]Cohen, L., “Generalized phase-space distribution functions”, J. of Math. Phys. 7 (1966) 781–786.CrossRef Google Scholar

[4]Condon, E. U., “Immersion of the Fourier transform in a continuous group of functional transformations”, Proc. Nat. Acad. Sci.USA 23 (1937) 158–164.CrossRef Google Scholar

[5]Deans, S. R., The Radon transform and some of its applications (John Wiley, New York, 1983).Google Scholar

[6]Dym, H. and McKean, H.P., Fourier Series and Integrals (Academic Press, New York, 1972).Google Scholar

[7]Folland, G. B., “Harmonic analysis in phase space”, in Annals of Mathematics Studies 122, (Princeton Univ. Press, Princeton, 1989).Google Scholar

[8]Mustard, D., “The fractional Fourier transform and the Wigner distribution”, J. Austral. Math. Soc. Ser.B 38 (1996) 209–219.CrossRef Google Scholar

[9]Mustard, D., “Lie group imbeddings of the Fourier transform and a new family of uncertainty principles”, Proceedings of the Centre for Mathematical Analysis 16 (1987) 211–222.Google Scholar

[10]Papoulis, A., Signal Analysis (McGraw-Hill, New York, 1977).Google Scholar

[11]Wigner, E., “On the quantum correction for thermodynamic equilibrium”, Phys. Rev. 40 (1932) 749–759.CrossRef Google Scholar

Crossref Citations

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Akay, O. and Boudreaux-Bartels, G.F. 2001. Fractional convolution and correlation via operator methods and an application to detection of linear FM signals. IEEE Transactions on Signal Processing, Vol. 49, Issue. 5, p. 979.

Alieva, Tatiana Calvo, Maria Luisa and Bastiaans, Martin J 2002. Power filtering ofnth order in the fractional Fourier domain. Journal of Physics A: Mathematical and General, Vol. 35, Issue. 36, p. 7779.

Nascov, Victor and Logofătu, Petre Cătălin 2009. Fast computation algorithm for the Rayleigh-Sommerfeld diffraction formula using a type of scaled convolution. Applied Optics, Vol. 48, Issue. 22, p. 4310.

Nes, Preben Gråberg 2011. Gabor Analysis for Non-Rectangular Lattices and the Fractional Fourier-Transform. Sampling Theory in Signal and Image Processing, Vol. 10, Issue. 3, p. 285.

De Bie, Hendrik and De Schepper, Nele 2012. The Fractional Clifford-Fourier Transform. Complex Analysis and Operator Theory, Vol. 6, Issue. 5, p. 1047.

De Bie, H. 2012. Clifford algebras, Fourier transforms, and quantum mechanics. Mathematical Methods in the Applied Sciences, Vol. 35, Issue. 18, p. 2198.

De Bie, Hendrik 2014. Operator Theory. p. 1.

Bujack, Roxana De Bie, Hendrik De Schepper, Nele and Scheuermann, Gerik 2014. Convolution Products for Hypercomplex Fourier Transforms. Journal of Mathematical Imaging and Vision, Vol. 48, Issue. 3, p. 606.

Bie, Hendrik De 2014. Operator Theory. p. 1.

De Bie, H. De Schepper, N. Ell, T.A. Rubrecht, K. and Sangwine, S.J. 2015. Connecting spatial and frequency domains for the quaternion Fourier transform. Applied Mathematics and Computation, Vol. 271, Issue. , p. 581.

Tenreiro Machado, J.A. 2015. Generalized convolution. Applied Mathematics and Computation, Vol. 257, Issue. , p. 34.

Bie, Hendrik De 2015. Operator Theory. p. 1651.

Roopkumar, Rajakumar 2016. Quaternionic one-dimensional fractional Fourier transform. Optik, Vol. 127, Issue. 24, p. 11657.

Batard, T. and Raeymaekers, T. 2016. Some Properties of the Spinor Fourier Transform. Advances in Applied Clifford Algebras, Vol. 26, Issue. 3, p. 933.

Cnudde, Lander and De Bie, Hendrik 2017. Slice Fourier transform and convolutions. Annali di Matematica Pura ed Applicata (1923 -), Vol. 196, Issue. 3, p. 837.

Hitzer, Eckhard 2017. General Steerable Two-sided Clifford Fourier Transform, Convolution and Mustard Convolution. Advances in Applied Clifford Algebras, Vol. 27, Issue. 3, p. 2215.

Hitzer, Eckhard 2017. General two-sided quaternion Fourier transform, convolution and Mustard convolution. Advances in Applied Clifford Algebras, Vol. 27, Issue. 1, p. 381.

Hitzer, Eckhard 2019. Special relativistic Fourier transformation and convolutions. Mathematical Methods in the Applied Sciences, Vol. 42, Issue. 7, p. 2244.

Castro-Valdez, Alfredo and Alvarez-Borrego, Josue 2020. Image Correlation Using Fractional Hermite Transform. IEEE Access, Vol. 8, Issue. , p. 28681.

Feng, Qiang and Wang, Rong-Bo 2020. Fractional convolution, correlation theorem and its application in filter design. Signal, Image and Video Processing, Vol. 14, Issue. 2, p. 351.

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