초록 ▼

This disclosure describes techniques of configuring capacitive comb fingers of an accelerometer resonator into discreet electrodes with drive electrodes and at least two sense electrodes. The routing of electrical signals is configured to produce parasitic feedthrough capacitances that are approxima

This disclosure describes techniques of configuring capacitive comb fingers of an accelerometer resonator into discreet electrodes with drive electrodes and at least two sense electrodes. The routing of electrical signals is configured to produce parasitic feedthrough capacitances that are approximately equal. The sense electrodes may be placed on opposite sides of the moving resonator beams such that the changes in capacitance with respect to displacement (e.g. dC/dx) are approximately equal in magnitude and opposite in sign. The arrangement may result in sense currents that are also opposite in sign and result in feedthrough currents of the same sign. The sense outputs from the resonators may be connected to a differential amplifier, such that the difference in output currents may mitigate the effect of the feedthrough currents and cancel parasitic feedthrough capacitance. Parasitic feedthrough capacitance may cause increased accelerometer noise and reduced bias stability.

대표청구항 ▼

1. A vibrating beam accelerometer (VBA) device, the device comprising: a resonator comprising: a resonator beam;a drive electrode; anda first sense electrode and a second sense electrode, wherein: the first sense electrode is located on a first side of the resonator beam,the second sense electrode i

1. A vibrating beam accelerometer (VBA) device, the device comprising: a resonator comprising: a resonator beam;a drive electrode; anda first sense electrode and a second sense electrode, wherein: the first sense electrode is located on a first side of the resonator beam,the second sense electrode is located on a second side of the resonator beam opposite the first side such that a first change in capacitance with respect to displacement (dC1/dx) for the first sense electrode is approximately equal in magnitude to a second change in capacitance with respect to displacement (dC2/dx) for the second sense electrode and opposite in sign; andelectrical signal routing: comprising: a drive signal path coupled to the drive electrode;a first sense signal path coupled to the first sense electrode; anda second sense signal path coupled to the second sense electrode,wherein the electrical signal routing is configured to produce: a first parasitic capacitance between the drive signal path and the first sense signal path that generates a first parasitic feedthrough current; anda second parasitic capacitance between the drive signal path and the second sense signal path, that generates a second parasitic feedthrough current, such that the first parasitic feedthrough current and the second parasitic feedthrough current are approximately equal in magnitude. 2. The device of claim 1, wherein the drive electrode is a first drive electrode on the first side of the resonator beam, the device further comprising a second drive electrode located on the second side of the resonator beam,wherein the first drive electrode is configured to receive a first drive signal,wherein the second drive electrode is configured to receive a second drive signal, andwherein the first drive signal is opposite in phase to the second drive signal. 3. The device of claim 2, wherein the first drive signal and the second drive signal are alternating current (AC) drive signals. 4. The device of claim 1, wherein the first sense electrode is coupled to a first anchored comb on the first side of the resonator beam, andwherein the second sense electrode is coupled to a second anchored comb on the second side of the resonator beam. 5. The device of claim 4, wherein the first sense electrode produces a positive current when the first anchored comb moves apart from the resonator beam, andwherein the second sense electrode produces a produce positive current when the second anchored comb moves closer to the resonator beam. 6. The device of claim 1 further comprising: a proof mass, wherein the proof mass is a pendulous proof mass;a support base defining a first plane;a resonator connection structure mechanically connected to the support base with an anchor, wherein the resonator connection structure is in a second plane parallel to the first plane;a hinge flexure configured to connect the pendulous proof mass to the resonator connection structure, wherein the hinge flexure suspends the pendulous proof mass parallel to the support base at the anchor, and wherein the pendulous proof mass rotates about the hinge flexure in the second plane in response to an acceleration of the device parallel to the first plane of the support base,wherein: the resonator is configured to connect the pendulous proof mass to the resonator connection structure and to flex in the second plane based on a rotation of the pendulous proof mass about the hinge flexure,the pendulous proof mass, the hinge flexure, and the one or more resonators are in the second plane. 7. The device of claim 6, further comprising a support flexure coupled to the pendulous proof mass, wherein the support flexure is configured to restrict out-of-plane motion of the pendulous proof mass with respect to the second plane. 8. The device of claim 6, wherein the resonator beam is configured to flex in a direction substantially perpendicular to a long axis of the resonator connection structure. 9. The device of claim 1, wherein the resonator is a first resonator, the device further comprising at least a second resonator, wherein each of the first resonator and the second resonator resonate at a respective driven resonant frequency. 10. A method comprising: receiving, by processing circuitry, one or more electrical signals indicative of a frequency of a first resonator beam and a frequency of a second resonator beam from a vibrating beam accelerometer (VBA), wherein the VBA comprises:a resonator comprising: the first resonator beam;a drive electrode; anda first sense electrode and a second sense electrode, wherein: the first sense electrode is located on a first side of the resonator beam,the second sense electrode is located on a second side of the resonator beam opposite the first side such that a first change in capacitance with respect to displacement (dC1/dx) for the first sense electrode is approximately equal in magnitude to a second change in capacitance with respect to displacement (dC2/dx) for the second sense electrode and opposite in sign; andelectrical signal routing: comprising: a drive signal path coupled to the drive electrode;a first sense signal path coupled to the first sense electrode; anda second sense signal path coupled to the second sense electrode,wherein the electrical signal routing is configured to produce: a first parasitic capacitance between the drive signal path and the first sense signal path that generates a first parasitic feedthrough current; anda second parasitic capacitance between the drive signal path and the second sense signal path, that generates a second parasitic feedthrough current, such that the first parasitic feedthrough current and the second parasitic feedthrough current are approximately equal in magnitude;determining, by the processing circuitry and based on the one or more electrical signals, the frequency of the first resonator beam and the frequency of the second resonator beam; andcalculating, by the processing circuitry and based on the frequency of the first resonator beam and the frequency of the second resonator beam, an acceleration of the VBA. 11. The method of claim 10, wherein the drive electrode is a first drive electrode on the first side of the resonator beam, the device further comprising a second drive electrode located on the second side of the resonator beam,wherein the first drive electrode is configured to receive a first drive signal,wherein the second drive electrode is configured to receive a second drive signal, andwherein the first drive signal is opposite in phase to the second drive signal. 12. The method of claim 10, wherein the resonator is a first resonator, the VBA further comprising a second resonator, the method further comprises calculating, based on the difference between the frequency of the first resonator and the frequency of the second resonator, the acceleration of the proof mass assembly. 13. A system for determining acceleration, the system comprising: processing circuitry coupled to a resonator driver circuit and configured to cause the resonator driver circuit to output a resonator driver signal;a vibrating beam accelerometer (VBA) device comprising a resonator configured to receive the resonator driver signal, the resonator comprising: a resonator beam;a drive electrode; anda first sense electrode and a second sense electrode, wherein: the first sense electrode is located on a first side of the resonator beam,the second sense electrode is located on a second side of the resonator beam opposite the first side such that a first change in capacitance with respect to displacement (dC1/dx) for the first sense electrode is approximately equal in magnitude to a second change in capacitance with respect to displacement (dC2/dx) for the second sense electrode and opposite in sign; andelectrical signal routing: comprising: a drive signal path coupled to the drive electrode;a first sense signal path coupled to the first sense electrode; anda second sense signal path coupled to the second sense electrode,wherein the electrical signal routing is configured to produce: a first parasitic capacitance between the drive signal path and the first sense signal path that generates a first parasitic feedthrough current; anda second parasitic capacitance between the drive signal path and the second sense signal path, that generates a second parasitic feedthrough current, such that the first parasitic feedthrough current and the second parasitic feedthrough current are approximately equal in magnitude. 14. The system of claim 13, wherein the drive electrode is a first drive electrode on the first side of the resonator beam, the device further comprising a second drive electrode located on the second side of the resonator beam,wherein the first drive electrode is configured to receive a first drive signal,wherein the second drive electrode is configured to receive a second drive signal, andwherein the first drive signal is opposite in phase to the second drive signal. 15. The system of claim 14, wherein the first drive signal and the second drive signal are alternating current (AC) drive signals. 16. The system of claim 13, wherein the first sense electrode is coupled to a first anchored comb on the first side of the resonator beam, andwherein the second sense electrode is coupled to a second anchored comb on the second side of the resonator beam. 17. The system of claim 16, wherein the first sense electrode produces a positive current when the first anchored comb moves apart from the resonator beam, andwherein the second sense electrode produces a produce positive current when the second anchored comb moves closer to the resonator beam. 18. The system of claim 13, wherein the VBA further comprises: a proof mass, wherein the proof mass is a pendulous proof mass;a support base defining a first plane;a resonator connection structure mechanically connected to the support base with an anchor, wherein the resonator connection structure is in a second plane parallel to the first plane;a hinge flexure configured to connect the pendulous proof mass to the resonator connection structure, wherein the hinge flexure suspends the pendulous proof mass parallel to the support base at the anchor, and wherein the pendulous proof mass rotates about the hinge flexure in the second plane in response to an acceleration of the device parallel to the first plane of the support base,wherein: the resonator is configured to connect the pendulous proof mass to the resonator connection structure and to flex in the second plane based on a rotation of the pendulous proof mass about the hinge flexure,the pendulous proof mass, the hinge flexure, and the one or more resonators are in the second plane. 19. The system of claim 13, further comprising a support flexure coupled to the pendulous proof mass, wherein the support flexure is configured to restrict out-of-plane motion of the pendulous proof mass with respect to the second plane. 20. The system of claim 13, wherein the resonator is a first resonator, the VBA further comprising a second resonator, wherein each of the first resonator and the second resonator resonate at a respective driven resonant frequency.