Claims
- 1. An accelerometer comprising:a housing defining a fluid cavity; at least one excitation electrode disposed within said housing; at least one output electrode disposed within said housing; at least one ground electrode disposed within said housing; and an electrolytic fluid essentially filling said fluid cavity.
- 2. The accelerometer defined in claim 1 further comprising at least a pair of said output electrodes connected to a differential amplifier.
- 3. The accelerometer defined in claim 2 wherein said differential amplifier is connected to a synchronous demodulator or means for averaging a signal from said differential amplifier.
- 4. The accelerometer defined in claim 1 wherein said housing is a toroid.
- 5. The accelerometer defined in claim 1 further comprising at least two ground electrodes disposed within said housing.
- 6. The accelerometer defined in claim 1 further comprising at least a pair of said output electrodes wherein said output electrodes and said ground electrode and said excitation electrode are electrically connected to a measuring circuit.
- 7. The accelerometer defined in claim 6 wherein said measuring circuit comprises a Wheatstone bridge.
- 8. A sensing device for measuring angular rates about an axis, said device comprising:a housing defining a fluid cavity, said housing comprising at least one excitation electrode, at least two output electrodes, and at least two ground electrodes; an electrolytic fluid essentially filling said cavity; and a measuring circuit wherein said output electrodes are connected to at least one differential amplifier and said differential amplifier is connected to a synchronous demodulator.
- 9. The device defined in claim 8 wherein said angular rates comprise rotational rates and said housing comprises a toroid.
- 10. The device defined in claim 9 wherein said output electrodes and/or said excitation electrode and/or said ground electrodes are essentially evenly aligned with a wall of said cavity.
- 11. The device defined in claim 8 wherein said differential amplifier comprises a monolithic instrumentation amplifier or a combination of amplifiers that creates an output signal proportional to the difference of two signal inputs while substantially rejecting the voltage in common to said two inputs.
- 12. The device defined in claim 8 wherein said synchronous demodulator comprises a circuit that chops an input signal at a rate controlled by a signal from said excitation electrode.
- 13. The device defined in claim 8 wherein said excitation electrode is connected to an oscillator and to said synchronous demodulator.
- 14. The device defined in claim 8 wherein said excitation electrode and said output electrodes are uniformly spaced within said cavity and said output electrodes and said ground electrodes are uniformly spaced within said cavity.
- 15. The device defined in claim 14 said excitation electrode and said output electrodes and said ground electrodes are electrically connected to a measuring circuit and wherein said measuring circuit comprises a Wheatstone Bridge.
- 16. The device defined in claim 8 wherein said excitation electrode adapted for excitation frequencies in the range from about 10 Hz to about 10 KHz.
- 17. The device defined in claim 8 wherein said synchronous demodulator is connected to a low pass filter.
- 18. A rotational rate sensor comprising:a housing defining a fluid cavity; at least one excitation electrode disposed within said housing and at least one output electrode disposed within said housing; at least one ground electrode disposed within said housing; and an electrolytic fluid sufficiently filling said fluid cavity so that all of said electrodes remain in contact with said fluid during less than about a 330 degree rotation of said housing.
- 19. The rotational rate sensor defined in claim 18 further comprising at least a pair of said output electrodes connected to a differential amplifier.
- 20. The rotational rate sensor defined in claim 19 wherein said differential amplifier is connected to a synchronous demodulator.
- 21. The rotational rate sensor defined in claim 20 wherein said housing is a toroid.
- 22. The rotational rate sensor defined in claim 21 further comprising at least two ground electrodes and at least two output electrodes disposed within said housing.
- 23. The rotational rate sensor defined in claim 22 wherein said excitation electrode and said output electrodes and said ground electrodes are electrically connected to a measuring circuit comprising a Wheatstone Bridge.
- 24. The accelerometer defined in claim 1 wherein said ground electrode comprising a porous material disposed within said housing.
- 25. The rotational rate sensor defined in claim 19 wherein said differential amplifier is connected to means for averaging an amplified signal.
- 26. The rotational rate sensor defined in claim 25 wherein said means for averaging an amplified signal comprises synchronous demodulation and/or a low pass filter, or a RMS converter.
- 27. A method for sensing the rotational rate of an object about an axis, said method comprising:mounting a rotational sensor to an object having at least one axis of rotation, said sensor comprising at least one excitation electrode, at least one output electrode, at least one ground electrode and an electrolytic fluid sufficiently filled in a fluid cavity to allow all of said electrodes to remain in contact with said fluid during less than about a 330 degree rotation of a housing containing said cavity; allowing rotational movement of said object about said axis; allowing movement of ions contained in said electrolytic fluid within said cavity in response to said rotational movement of said object; and measuring said movement of ions from said excitation electrode toward at least one of said output electrodes to create a signal representing at least some degree of rotation of said object.
Government Interests
The United States Government has rights in this invention pursuant to Contract No. W-7405-ENG-48 between the United States Department of Energy and the University of California for the operation of Lawrence Livermore National Laboratory.
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