Title :
High-Q whispering gallery traveling wave resonators for oscillator frequency stabilization
Author :
Tobar, Michael E. ; Ivanov, Eugene N. ; Blondy, Pierre ; Cros, Dominique ; Guillon, Pierre
Author_Institution :
Dept. of Phys., Western Australia Univ., Nedlands, WA, Australia
fDate :
3/1/2000 12:00:00 AM
Abstract :
Usually a frequency-stabilized standing wave resonator-oscillator incorporating a resonator as a frequency discriminator requires a circulator to separate the injected and reflected wave, A ferrite circulator is a noisy device and can limit the phase noise or frequency stability. Moreover, we show that the noise in a circulator varies, and detailed low noise measurements are necessary to choose an appropriate quiet circulator. Thus, by realizing a configuration that does not require a circulator, an improvement in performance and reliability can be obtained. A solution to this problem is to design a high-Q whispering gallery traveling wave (WGTW) resonator. This device naturally separates the injected and reflected wave in the same way as a ring cavity at optical frequencies, without degrading the frequency discrimination. Q-factor measurements of a WGTW sapphire resonator are presented, along with a derivation of critical parameters to maximize the frequency discrimination. New measurements of noise in ferrite circulators and isolators have also been made, which is followed with a discussion on oscillator design.
Keywords :
Q-factor; dielectric resonators; frequency stability; reliability; sapphire; Al/sub 2/O/sub 3/; Q-factor measurements; critical parameters; frequency discrimination; high-Q whispering gallery traveling wave resonators; oscillator design; oscillator frequency stabilization; reliability; ring cavity; sapphire; Degradation; Ferrites; Noise measurement; Optical devices; Optical noise; Optical resonators; Oscillators; Phase noise; Resonant frequency; Stability;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
