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An analysis method for asymmetric resonator transmission applied to superconducting devices

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arxiv 1108.3117 v3 pith:7754NGW2 submitted 2011-08-15 cond-mat.supr-con

An analysis method for asymmetric resonator transmission applied to superconducting devices

classification cond-mat.supr-con
keywords methodasymmetriclineshapetransmissionanalysisresonanceresonator
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We examine the transmission through nonideal microwave resonant circuits. The general analytical resonance line shape is derived for both inductive and capacitive coupling with mismatched input and output transmission impedances, and it is found that for certain non-ideal conditions the line shape is asymmetric. We describe an analysis method for extracting an accurate internal quality factor ($Q_i$), the Diameter Correction Method (DCM), and compare it to the conventional method used for millikelvin resonator measurements, the $\phi$ Rotation Method ($\phi$RM). We analytically find that the $\phi$RM deterministically overestimates $Q_i$ when the asymmetry of the resonance line shape is high, and that this error is eliminated with the DCM. A consistent discrepancy between the two methods is observed when they are used to analyze both simulations from a numerical linear solver and data from asymmetric coplanar superconducting thin-film resonators.

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