Title :
A Temperature Compensation Concept for a Micromachined Film Bulk Acoustic Resonator Oscillator
Author :
Xu Zhang ; Wencheng Xu ; Junseok Chae
Author_Institution :
Sch. of Electr. Comput. & Energy Eng., Arizona State Univ., Tempe, AZ, USA
Abstract :
We present a temperature compensation technique of a film bulk acoustic resonator (FBAR)-based oscillator by tuning the supply voltage of the oscillator. The FBAR-based oscillator uses a high-Q FBAR that is made of a thin ZnO piezoelectric film sandwiched by two electrodes. The FBAR is significantly sensitive to temperature change, consequently resulting in large temperature sensitivity of the FBAR-based oscillator. In this paper, we present a temperature compensation technique that improves the temperature coefficient (TCfosc) of a 1.625-GHz FBAR-based oscillator from -118 ppm/K to less than 1 ppm/K by tuning the supply voltage of the oscillator. The tuning technique has a large frequency tunability of -4305 ppm/V.
Keywords :
acoustic resonators; bulk acoustic wave devices; compensation; dielectric resonator oscillators; micromechanical resonators; piezoelectric thin films; zinc compounds; ZnO; electrodes; frequency 1.625 GHz; frequency tunability; high-Q FBAR; micromachined film bulk acoustic resonator oscillator; supply voltage; temperature coefficient; temperature compensation; temperature sensitivity; thin piezoelectric film; tuning technique; Film bulk acoustic resonators; Frequency measurement; Oscillators; Resonant frequency; Temperature measurement; Temperature sensors; Tuning; FBAR; FBAR Oscillator; FBAR oscillator; Frequency tuning; Piezoelectric transducers; Temperature compensation; frequency tuning; temperature compensation;
Journal_Title :
Sensors Journal, IEEE
DOI :
10.1109/JSEN.2015.2438323
