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Cooled, ultrahigh Q, sapphire dielectric resonators for low-noise, microwave signal generation

M.M. DriscollJ.T. HaynesR.A. JelenR.W. WeinertJ. R. GavalerJ. TalvacchioG. R. WagnerK.A. ZakiXiaopeng Liang

Year: 1992 Journal:   IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control Vol: 39 (3)Pages: 405-411   Publisher: Institute of Electrical and Electronics Engineers
DOI: 10.1109/58.143174
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Abstract

Ultra-high Q, X-band resonators, used in a frequency discriminator for stabilization of a low-noise signal generator, can provide a means of obtaining significant reduction in phase noise levels. Resonator unloaded Qs on the order of 500 K can be obtained in sapphire dielectric resonator (DR) operating on a low-order (i.e. TE(01)) mode at 77 K and employing high-temperature superconducting (HTS) films installed in the DR enclosure covers. Rigorous analysis for the determination of resonator frequency, modes, and unloaded Q have been carried out using mode matching techniques. Trade-off studies have been performed to select resonator dimensions for the optimum mode yielding highest unloaded Q and widest spurious mode separation. Field distributions within the resonator have been computed to enable practical excitation of the required mode. The results of both analysis and prototype device evaluation experiments are compared for resonators fabricated using enclosures consisting of conventional, metal sidewalls and covers employing HTS films as a function of cover conductivity.

Keywords:
Sapphire Materials science Microwave Dielectric Resonator SIGNAL (programming language) Dielectric resonator Noise (video) Acoustics Phase noise Optoelectronics Electronic engineering Electrical engineering Optics Physics Engineering Computer science Telecommunications

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Citation History

Topics

Radio Frequency Integrated Circuit Design
Physical Sciences →  Engineering →  Electrical and Electronic Engineering
Microwave Engineering and Waveguides
Physical Sciences →  Engineering →  Electrical and Electronic Engineering
Advanced Frequency and Time Standards
Physical Sciences →  Physics and Astronomy →  Atomic and Molecular Physics, and Optics

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