2019
DOI: 10.1016/j.cma.2019.03.002
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Uncertainty quantification for Maxwell’s eigenproblem based on isogeometric analysis and mode tracking

Abstract: The electromagnetic field distribution as well as the resonating frequency of various modes in superconducting cavities used in particle accelerators for example are sensitive to small geometry deformations. The occurring variations are motivated by measurements of an available set of resonators from which we propose to extract a small number of relevant and independent deformations by using a truncated Karhunen-Loève expansion. The random deformations are used in an expressive uncertainty quantification workf… Show more

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Cited by 21 publications
(14 citation statements)
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“…Proof. Assertion a) has been already shown by the derivation of the boundary integral formulation (6). For assertion b) note that V V V κ j j j is a solution of Maxwell's equation in Ω [21,Sect.…”
Section: Recasting the Eigenvalue Problemmentioning
confidence: 68%
See 1 more Smart Citation
“…Proof. Assertion a) has been already shown by the derivation of the boundary integral formulation (6). For assertion b) note that V V V κ j j j is a solution of Maxwell's equation in Ω [21,Sect.…”
Section: Recasting the Eigenvalue Problemmentioning
confidence: 68%
“…There are also other, more advanced applications which have such high demands on accuracy. One is presented by Georg et al [6], who show that even higher accuracies than those already achievable are required to simulate eccentricities.…”
Section: Motivationmentioning
confidence: 99%
“…While the tuners still can compensate for manufacturing errors and deformations due to Lorentz detuning, conventional numerical methods struggle to resolve changes of this magnitude, since they happen within a relative margin of roughly 10 −7 , and there are other examples of applications, where such high demands of accuracy are desired of simulations. One other example is presented by Georg et al [55], who explain that one must resolve eccentric deformations of cavities within a relative error margin of 10 −6 w.r.t. the operating frequency.…”
Section: Motivation: the Cavity Problemmentioning
confidence: 99%
“…There are also other, more advanced applications which have high demands on accuracy. One is presented by Georg et al, 6 who show that even higher accuracies than those already achievable are required to simulate eccentricities.…”
Section: Motivationmentioning
confidence: 99%