Title :
In-situ ovenization of Lamé-mode silicon resonators for temperature compensation
Author :
Yunhan Chen ; Ng, Eldwin J. ; Yushi Yang ; Chae Hyuck Ahn ; Flader, Ian ; Kenny, Thomas W.
Author_Institution :
Stanford Univ., Stanford, CA, USA
Abstract :
This paper reports an inside-encapsulation ovenization method for the temperature compensation of Lamé-mode epi-sealed silicon resonators. With this method, the square Lamé-mode resonator itself acts both as a thermometer and a heater, which allows for simultaneous in situ sensing and control of the operating temperature. In this device, only the resonating element is heated, reducing the power consumption and the thermal time constant, relative to approaches which control the temperature of an entire MEMS chip or system. Preliminary results of real-time frequency compensation achieve a frequency stability of ~5ppm over -40~+80°C without the need for sophisticated control schemes.
Keywords :
compensation; encapsulation; micromechanical resonators; thermometers; Lamé-mode epi-sealed silicon resonators; MEMS chip; frequency stability; heater; inside-encapsulation ovenization method; power consumption; real-time frequency compensation; resonating element; square Lamé-mode resonator; temperature compensation; thermal time constant; thermometer; Electrical resistance measurement; Micromechanical devices; Resistance; Resonant frequency; Temperature measurement; Temperature sensors; Thermal stability;
Conference_Titel :
Micro Electro Mechanical Systems (MEMS), 2015 28th IEEE International Conference on
Conference_Location :
Estoril
DOI :
10.1109/MEMSYS.2015.7051082
