Interface circuits for readout and control of a micro-hemispherical resonating gyroscope

Mayberry, Curtis Lee

12 January 2015

Gyroscopes are inertial sensors that measure the rate or angle of rotation. One of the most promising technologies for reaching a high-performance MEMS gyroscope has been development of the micro-hemispherical shell resonator. (μHSR) This thesis presents the electronic control and read-out interface that has been developed to turn the μHSR into a fully functional micro-hemispherical resonating gyroscope (μHRG) capable of measuring the rate of rotation. First, the μHSR was characterized, which both enabled the design of the interface and led to new insights into the linearity and feed-through characteristics of the μHSR. Then a detailed analysis of the rate mode interface including calculations and simulations was performed. This interface was then implemented on custom printed circuit boards for both the analog front-end and analog back-end, along with a custom on-board vacuum chamber and chassis to house the μHSR and interface electronics. Finally the performance of the rate mode gyroscope interface was characterized, showing a linear scale factor of 8.57 mv/deg/s, an angle random walk (ARW) of 34 deg/sqrt(hr) and a bias instability of 330 deg/hr.

uHRG

µHRG

MEMS

CVG

Coriolis

TIA

AM

FM

Micro-hemispherical resonating gyroscope

3D-HARPSS

High-Q

Gyroscopes

Gyroscopic instruments

Gyroscope

Vibratory

Coriolis vibratory gyroscope

Interface

Circuits

Transimpedance amplifier

Rate integrating

Inertial sensor

Sensor

Oscillator

Analog

Control

Electrostatic

Capacitive

Noise

Characterization

Mode-matching

Wine-glass

Duffing

Non-linearity

Feed-through cancellation

Vibratory gyroscopes

Polysilicon