Title :
An overview of quartz MEMS devices
Author_Institution :
Epson Toyocom Corp., Nagano, Japan
Abstract :
The most outstanding feature of quartz crystal device is its frequency stability in wide range of temperature. In the last ten years, miniaturization of quartz devices has been accelerated. The newest resonators are 1/500 in size compared to those in ten years ago. Miniaturization of devices in general sacrifices its quality factor (Q value), S/N ratio, frequency-temperature stability, and product uniformity. QMEMS is a promising mass-production process to solve problems mentioned above. The flexibility of design makes possible quartz devices with 3 dimensional configurations. As a result, mechanical energy dispersion was prevented efficiently by the isolation design of miniature tuning fork and gyro sensor. Using the QMEMS process, the frequency stability in range of less than 2×10-7 can be guaranteed in TCXO. These advances in leaps of properties were supported by QMEMS technology. At the same time QMEMS technology is an efficient mass production system to make uniform resonators with small tolerance.
Keywords :
Q-factor; crystal resonators; frequency stability; micromechanical resonators; Q value; QMEMS process; frequency-temperature stability; gyrosensor; isolation design; mass-production process; mechanical energy dispersion; miniature tuning fork; product uniformity; quality factor; quartz MEMS devices; quartz crystal device; quartz device miniaturization; Capacitance; Crystals; Resonant frequency; Temperature; Temperature sensors; Thermal stability; Vibrations;
Conference_Titel :
Frequency Control Symposium (FCS), 2010 IEEE International
Conference_Location :
Newport Beach, CA
Print_ISBN :
978-1-4244-6399-2
DOI :
10.1109/FREQ.2010.5556352
