Title :
Low noise, UHF oscillators utilizing high overtone, lateral-field excitation, lithium tantalate resonators
Author :
Driscoll, M.M. ; Jelen, R.A. ; Weinert, R.W. ; Krishnaswamy, S.V. ; McAvoy, B.R.
Author_Institution :
Westinghouse Electron. Syst. Group, Baltimore, MD, USA
Abstract :
The design and fabrication of high overtone, lateral-field excitation (LFE), LiTaO3 resonators exhibiting unloaded Q values five times greater than those of similar frequency quartz surface acoustic wave (SAW) resonators were reported by R.W. Weinert et al. (1989). Recent improvements of that work with regard to suppression of resonator spurious modes are described, as is the design and performance of low-noise UHF oscillators incorporating the resonators as frequency control elements. Although excellent short-term frequency stability (near-carrier phase noise) performance has been demonstrated, resonator-controlled oscillator initial frequency drift rates are relatively high and appear to be reduced by electrode pattern design modifications made to obtain spurious modes suppression
Keywords :
acoustic resonators; electron device noise; lithium compounds; LiTaO3 resonators; UHF oscillators; design; electrode pattern design; frequency control elements; frequency stability; high overtone; lateral-field excitation; low noise; near-carrier phase noise; performance; unloaded Q values; Acoustic noise; Acoustic waves; Electrodes; Fabrication; Frequency control; Oscillators; Phase noise; Resonant frequency; Stability; Surface acoustic waves;
Conference_Titel :
Ultrasonics Symposium, 1991. Proceedings., IEEE 1991
Conference_Location :
Orlando, FL
DOI :
10.1109/ULTSYM.1991.234206
