Solid-state gyroscopes and planar three-axis inertial measurement unit
First Claim
1. A z-axial solid-state gyroscope, manufactured by a conductive material and comprising:
- two sets of a proof mass and two driver bodies suspended between two parallel plates by an elastic beam assembly so that they can move along a first axis and a second axis parallel to a surface of the plates;
each surface of each driver body forming a plurality of grooves perpendicular to the first axis, the surface of each plate facing to each driver body being formed of two sets of driving electrodes, respectively including a number of stripe electrodes perpendicular to the first axis, the two sets of driving stripe electrodes being interposed with each other and being formed of two sets of driving capacitors with the corresponding surface of the driver body;
each surface of each proof mass forming a plurality of grooves perpendicular to the second axis, the surface of each plate facing to the proof mass being formed of two sets of sensing electrodes, respectively including a number of stripe electrodes parallel to the grooves of the proof mass, the two sets of sensing stripe electrodes being interposed with each other and being formed of two sets of sensing capacitors with the corresponding surface of the proof mass;
the capacitances thereof changing with the movement of the proof masses along the second axis;
the driving capacitors of the two driver bodies corresponding to each proof mass are divided into two parts;
the first part of the driving capacitors being excited to drive the proof mass to vibrate in opposite direction along the first axis; and
the second part of the driving capacitors being able to sense a vibration amplitude signal and an acceleration of the proof mass along the first axis, and feedback it to the first part of the driving capacitors to control the vibration amplitude of the proof mass and to rebalance of the specific force along the first axis;
wherein the sensing capacitors is able to sense a vibration amplitude signal and an displacement of the proof mass along the second axis; and
output signals of each proof mass induced by an angular velocity and an acceleration are respectively a AC signal and a DC signal, which are separated into an angular velocity signal and an acceleration signal by a signal processing technique.
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Abstract
The present invention relates to a z-axial solid-state gyroscope. Its main configuration is manufactured with a conductive material and includes two sets of a proof mass and two driver bodies suspended between two plates by an elastic beam assembly. Both surfaces of the driver bodies and the proof masses respectively include a number of grooves respectively perpendicular to a first axis and a second axis. The surfaces of the driver bodies and the proof masses and the corresponding stripe electrodes of the plates thereof are respectively formed a driving capacitors and a sensing capacitors. The driving capacitor drives the proof masses to vibrate in the opposite direction along the first axis. If a z-axial angular velocity input, a Coriolis force makes the two masses vibrate in the opposite direction along the second axis. If a first axial acceleration input, a specific force makes the two masses move in the same direction along the first axis. If a second axial acceleration input, a specific force makes the two masses move in the same direction along the second axis. Both inertial forces make the sensing capacitances change. One z-axial solid-state gyroscopes and two in-plane axial gyroscopes can be designed on a single chip to form a complete three-axis inertial measurement unit.
23 Citations
6 Claims
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1. A z-axial solid-state gyroscope, manufactured by a conductive material and comprising:
- two sets of a proof mass and two driver bodies suspended between two parallel plates by an elastic beam assembly so that they can move along a first axis and a second axis parallel to a surface of the plates;
each surface of each driver body forming a plurality of grooves perpendicular to the first axis, the surface of each plate facing to each driver body being formed of two sets of driving electrodes, respectively including a number of stripe electrodes perpendicular to the first axis, the two sets of driving stripe electrodes being interposed with each other and being formed of two sets of driving capacitors with the corresponding surface of the driver body;
each surface of each proof mass forming a plurality of grooves perpendicular to the second axis, the surface of each plate facing to the proof mass being formed of two sets of sensing electrodes, respectively including a number of stripe electrodes parallel to the grooves of the proof mass, the two sets of sensing stripe electrodes being interposed with each other and being formed of two sets of sensing capacitors with the corresponding surface of the proof mass;
the capacitances thereof changing with the movement of the proof masses along the second axis;
the driving capacitors of the two driver bodies corresponding to each proof mass are divided into two parts;
the first part of the driving capacitors being excited to drive the proof mass to vibrate in opposite direction along the first axis; and
the second part of the driving capacitors being able to sense a vibration amplitude signal and an acceleration of the proof mass along the first axis, and feedback it to the first part of the driving capacitors to control the vibration amplitude of the proof mass and to rebalance of the specific force along the first axis;
whereinthe sensing capacitors is able to sense a vibration amplitude signal and an displacement of the proof mass along the second axis; and
output signals of each proof mass induced by an angular velocity and an acceleration are respectively a AC signal and a DC signal, which are separated into an angular velocity signal and an acceleration signal by a signal processing technique. - View Dependent Claims (2, 3, 4, 5, 6)
- two sets of a proof mass and two driver bodies suspended between two parallel plates by an elastic beam assembly so that they can move along a first axis and a second axis parallel to a surface of the plates;
Specification