Title :
Temperature sensor based on quartz tuning-fork resonator
Author :
Jun, Xu ; Hong, Ai ; Li Xin ; Quan-Li, Li
Author_Institution :
Coll. of Comput. & Control, Harbin Univ. of Sci. & Technol., China
Abstract :
A miniature thermo-sensitive quartz tuning-fork resonator (TSQFR), working in the flexural vibration mode as a temperature sensor, has been expressed. This type of resonator, designed with a new doubly rotated ZYtw-cut, the rotation angle Φ and θ of which must be in the range 110°±1° and 14°±2°, shows nearly a linear response with a sensitivity between 53 ppm°C-1 and 59 ppm°C-1 with temperature range from -30 to 150°C. Precise temperature versus frequency analyses of the resonators has been carried out and a least mean squared (LMS) curve fitting algorithm can be used to compute the temperature values quantitatively. Experimentally, the sensor showed an accuracy of 0.05°C with a resolution of 10-3°C for a 2 s response time.
Keywords :
crystal resonators; curve fitting; least mean squares methods; temperature sensors; vibrations; -30 to 150 degC; 2 s; LMS; TSQFR; doubly rotated ZYtw-cut; flexural vibration mode; least mean squared curve fit algorithm; linear response; piezo-resonance; piezoelectric resonance device; quartz bulk resonators; temperature range; temperature sensor; thermo-sensitive quartz tuning-fork resonator; Energy consumption; Frequency; Magnetic field measurement; Magnetic sensors; Power measurement; Resonance; Signal processing; Temperature control; Temperature distribution; Temperature sensors;
Conference_Titel :
Solid-State and Integrated Circuits Technology, 2004. Proceedings. 7th International Conference on
Print_ISBN :
0-7803-8511-X
DOI :
10.1109/ICSICT.2004.1435166
