Paper detail

Design optimization of mode-matched bulk-mode piezoelectric micro-gyroscopes through modal analysis

Bulk piezoelectric micro-gyroscope is a miniaturized inertial sensor that uses a differential thickness-shear bulk mode of a PZT block as the drive mode of the gyroscope. In the paper, a second differential thickness-extensional mode is identified for the sense mode and mode-matching is proposed for the first time by proper design of the device geomtries. Through finite element modal analysis, the frequencies of drive mode and sense mode are obtained when the length of the PZT block varies from 4.8mm to 5.6mm and the width of the PZT block varies from 3.0mm to 4.0mm. Using a fitting method, the empirical formulae with an excellent fit are induced to predict the influence of the length and the width of the PZT block on the drive and sense mode frequencies. Based on these empirical formulae, the mode-matching equations are introduced. The analysis results show that for a given thickness of the PZT block, the effect of the width on the drive mode frequency is prominant. Conversly, the effect of length on the sense mode frequency is dominant. The resonance frequencies, kinetic energy ratios, scale factors of gyroscope are compared to evaluate the mode quality. The results show that the kinetic energy in y-axis direction of the drive mode and the kinetic energy in z-axis direction of the sense mode increase with the thickness of the PZT block, and consequently the scale factor of the gyroscope increases. For a constant thickness of the PZT block the scale factor will decrease as the length increases. Through design optimization we present a 20 times improvement in the scale factor of the mode-matched gyroscope. Given the thickness of PZT block, the length and the width will be determined by the mode-matching equations mentioned. Generally, the analysis suggests that the resolution of the gyroscope improves by increasing the thickness PZT block.