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Electromagnetic cavity Helmholtz equation

by Peijun Li A, Aihua Wood B, Variational Formulations , 2012
"... Existence and uniqueness Finite element method a b s t r a c t Here considered is the mathematical analysis and numerical computation of the electro-magnetic wave scattering by multiple cavities embedded in an infinite ground plane. Above the ground plane the space is filled with a homogeneous mediu ..."
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Existence and uniqueness Finite element method a b s t r a c t Here considered is the mathematical analysis and numerical computation of the electro-magnetic wave scattering by multiple cavities embedded in an infinite ground plane. Above the ground plane the space is filled with a homogeneous

Shape determination for deformed electromagnetic cavities

by Volkan Akçelik, Kwok Ko, Lie-quan Lee, Zenghai Li, Cho-kuen Ng, Liling Xiao A - J. Comp. Phys
"... The measured physical parameters of a superconducting cavity differ from those of the designed ideal cavity. This is due to shape deviations caused by both loose machine tolerances during fabrication and by the tuning process for the accelerating mode. We present a shape determination algorithm to s ..."
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The measured physical parameters of a superconducting cavity differ from those of the designed ideal cavity. This is due to shape deviations caused by both loose machine tolerances during fabrication and by the tuning process for the accelerating mode. We present a shape determination algorithm

Potentials for a Rectangular Electromagnetic Cavity

by Kirk T. Mcdonald
"... Deduce scalar and vector potentials relevant to electromagnetic modes in a rectangular cavity of dimensions dx ≥ dy ≥ dz, assuming the walls to be perfect conductors, and the interior of the cavity to be vacuum. 2 Solution For the case of a cylindrical cavity, see [1]. 2.1 E and B Fields of the Cavi ..."
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Deduce scalar and vector potentials relevant to electromagnetic modes in a rectangular cavity of dimensions dx ≥ dy ≥ dz, assuming the walls to be perfect conductors, and the interior of the cavity to be vacuum. 2 Solution For the case of a cylindrical cavity, see [1]. 2.1 E and B Fields

Potentials for a Cylindrical Electromagnetic Cavity

by Juan Gallardo, Kirk T. Mcdonald
"... Deduce scalar and vector potentials relevant to the lowest electromagnetic mode in a right circular cylindrical cavity of radius R and axial extend 2D, assuming the walls to be perfect conductors, and the interior of the cavity to be vacuum. 2 Solution For the case of a rectangular cavity, see [1]. ..."
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Deduce scalar and vector potentials relevant to the lowest electromagnetic mode in a right circular cylindrical cavity of radius R and axial extend 2D, assuming the walls to be perfect conductors, and the interior of the cavity to be vacuum. 2 Solution For the case of a rectangular cavity, see [1

Experimental Study of Pulsed Heating of Electromagnetic Cavities

by D. P. Pritzkau, A. Menegat, R. H. Siemann, T. G. Lee, D. U. L. Yu - in Proceedings of the 1997 Particle Accelerator Conference , 1998
"... An experiment to study the effects of pulsed heating in electromagnetic cavities will be performed. Pulsed heating is believed to be the limiting mechanism of high acceleration gradients at short wavelengths. A cylindrical cavity operated in the TE011mode at a frequency of 11.424 GHz will be used. A ..."
Abstract - Cited by 4 (2 self) - Add to MetaCart
An experiment to study the effects of pulsed heating in electromagnetic cavities will be performed. Pulsed heating is believed to be the limiting mechanism of high acceleration gradients at short wavelengths. A cylindrical cavity operated in the TE011mode at a frequency of 11.424 GHz will be used

New Journal of Physics Creating electromagnetic cavities using transformation optics

by V Ginis, P Tassin, J Danckaert, C M Soukoulis, I Veretennicoff , 2012
"... Creating electromagnetic cavities using transformation optics This article has been downloaded from IOPscience. Please scroll down to see the full text article. ..."
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Creating electromagnetic cavities using transformation optics This article has been downloaded from IOPscience. Please scroll down to see the full text article.

ELECTROMAGNETIC CAVITY TESTS OF LORENTZ INVARIANCE ON EARTH AND IN SPACE

by M. Nagel, E. V. Kovalchuck, A. Peters
"... ar ..."
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The Viterbi algorithm

by G. David Forney - Proceedings of the IEEE , 1973
"... vol. 6, no. 8, pp. 211-220, 1951. [7] J. L. Anderson and J. W..Ryon, “Electromagnetic radiation in accelerated systems, ” Phys. Rev., vol. 181, pp. 1765-1775, 1969. [8] C. V. Heer, “Resonant frequencies of an electromagnetic cavity in an accelerated system of reference, ” Phys. Reu., vol. 134, pp. A ..."
Abstract - Cited by 985 (3 self) - Add to MetaCart
vol. 6, no. 8, pp. 211-220, 1951. [7] J. L. Anderson and J. W..Ryon, “Electromagnetic radiation in accelerated systems, ” Phys. Rev., vol. 181, pp. 1765-1775, 1969. [8] C. V. Heer, “Resonant frequencies of an electromagnetic cavity in an accelerated system of reference, ” Phys. Reu., vol. 134, pp

Excitation of a Rectangular Electromagnetic Cavity by a Passing, Relativistic Electron

by Kirk T. Mcdonald
"... Deduce the strength of the lowest mode of a rectangular electromagnetic cavity when excited by a relativistic electron of charge −e and speed v ≈ c, wherec is the speed of light in vacuum. The rectangular cavity has dimensions dx ≥ dy ≥ dz, and the electron moves parallel to the z-axis. The cavity w ..."
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Deduce the strength of the lowest mode of a rectangular electromagnetic cavity when excited by a relativistic electron of charge −e and speed v ≈ c, wherec is the speed of light in vacuum. The rectangular cavity has dimensions dx ≥ dy ≥ dz, and the electron moves parallel to the z-axis. The cavity

Determination of electromagnetic cavity modes using the Finite Difference Frequency-Domain Method

by J. Manzanares-martínez, D. Moctezuma-enriquez, R. Archuleta-garcía , 2010
"... In this communication we propose a numerical determination of the electromagnetic modes in a cavity by using the Finite Difference Frequency-Domain Method. We first derive the analytical solution of the system and subsequently we introduce the numerical approximation. The cavity modes are obtained b ..."
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In this communication we propose a numerical determination of the electromagnetic modes in a cavity by using the Finite Difference Frequency-Domain Method. We first derive the analytical solution of the system and subsequently we introduce the numerical approximation. The cavity modes are obtained
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