Beams generation by aperture field spectra

This paper discusses a novel method for computing aperture radiated fields by means of two new types of circular domain beams with azimuthally phase variation. These circular domain beams rigorously respect the wave equation and in their vector form, Maxwell's equations. The beam expansion of a...

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Bibliographic Details
Main Authors: Casaletti, M., Maci, S., Skokic, S.
Format: Conference Proceeding
Language:English
Subjects:
aperture field
Apertures
beam expansion
Closed-form solution
Electric fields
Electromagnetic scattering
Fourier series
Manganese
Presses
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Summary:This paper discusses a novel method for computing aperture radiated fields by means of two new types of circular domain beams with azimuthally phase variation. These circular domain beams rigorously respect the wave equation and in their vector form, Maxwell's equations. The beam expansion of an aperture radiated field is simply obtained by first expanding the field spectrum in the aperture plane in terms of an angular Fourier series and next representing the radial spectral coefficients in terms of complex exponentials obtained by the Generalized Pencil-of-Function method (GPOF) method. The starting radiation integral is this way reduced to a double sum of wave objects which can be computed analytically in both space and spectral domain. The vector form can be obtained through the use of vector potentials. This paper will only deal with the development and the propagation of the new wave objects. An example is presented to shows how the two different typologies of these new wave objects can be used to reconstruct the near and far field radiated by a circular apertures. The results are compared to those obtained via direct integration of the radiation integral. The comparison with other beam expansion will be presented in the final paper.
ISSN:1522-3965
1947-1491
DOI:10.1109/APS.2011.5996711