Accelerometers
First Claim
1. A capacitive accelerometer comprising:
- a substantially planar proof mass mounted to a fixed substrate by flexible support legs so as to be linearly moveable in an in-plane sensing direction in response to an applied acceleration;
the proof mass comprising first and second sets of moveable capacitive electrode fingers extending from the proof mass perpendicular to the sensing direction and laterally spaced in the sensing direction;
first and second fixed capacitor electrodes comprising first and second sets of fixed capacitive electrode fingers extending perpendicular to the sensing direction and laterally spaced in the sensing direction;
the first set of fixed capacitive electrode fingers arranged to interdigitate with an offset with the first set of moveable capacitive electrode fingers of the proof mass, with a first offset in one direction from a median line to define a first lateral spacing therebetween, and the second set of fixed capacitive electrode fingers arranged to interdigitate with the second set of moveable capacitive electrode fingers of the proof mass, with a second offset in the opposite direction from a median line to define a second lateral spacing therebetween;
wherein the interdigitated capacitive electrode fingers are mounted in a gaseous medium that provides a damping effect counteracting relative displacement of the capacitive electrode fingers when the proof mass moves in response to an applied acceleration;
at least one further fixed capacitor electrode comprising a plurality of further fixed capacitive electrode fingers extending along the sensing direction;
the proof mass comprising a plurality of moveable capacitive electrode fingers extending from the proof mass along the sensing direction and arranged to interdigitate with the plurality of further fixed capacitive electrode fingers of the at least one further fixed capacitor electrode; and
means for applying a voltage to the at least one further fixed capacitor electrode to apply an electrostatic force to the plurality of moveable capacitive electrode fingers that acts to pull the proof mass towards the at least one further fixed capacitor electrode and thereby reduces the first and/or second lateral spacings;
wherein the least one further fixed capacitor electrode comprises a fixed capacitor electrode arranged centrally of the proof mass; and
wherein the proof mass comprises a first moveable frame for the first set of interdigitated capacitive electrode fingers arranged on one side of the fixed capacitor electrode and a second moveable frame for the second set of interdigitated capacitive electrode fingers arranged on an opposite side of the fixed capacitor electrode.
1 Assignment
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Accused Products
Abstract
A capacitive accelerometer including: at least one additional fixed capacitor electrode with a plurality of additional fixed capacitive electrode fingers extending along the sensing direction. The proof mass comprises a plurality of moveable capacitive electrode fingers extending from the proof mass along the sensing direction and arranged to interdigitate with the plurality of additional fixed capacitive electrode fingers of the at least one additional fixed capacitor electrode. A means is provided for applying a voltage to the at least one additional fixed capacitor electrode to apply an electrostatic force to the plurality of moveable capacitive electrode fingers that acts to pull the proof mass towards the at least one further fixed capacitor electrode and thereby reduces the lateral spacings between the movable capacitive electrode fingers of the proof mass and the first and second sets of fixed capacitive electrode fingers that provide electrostatic forces for sensing purposes.
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Citations
13 Claims
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1. A capacitive accelerometer comprising:
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a substantially planar proof mass mounted to a fixed substrate by flexible support legs so as to be linearly moveable in an in-plane sensing direction in response to an applied acceleration; the proof mass comprising first and second sets of moveable capacitive electrode fingers extending from the proof mass perpendicular to the sensing direction and laterally spaced in the sensing direction; first and second fixed capacitor electrodes comprising first and second sets of fixed capacitive electrode fingers extending perpendicular to the sensing direction and laterally spaced in the sensing direction; the first set of fixed capacitive electrode fingers arranged to interdigitate with an offset with the first set of moveable capacitive electrode fingers of the proof mass, with a first offset in one direction from a median line to define a first lateral spacing therebetween, and the second set of fixed capacitive electrode fingers arranged to interdigitate with the second set of moveable capacitive electrode fingers of the proof mass, with a second offset in the opposite direction from a median line to define a second lateral spacing therebetween; wherein the interdigitated capacitive electrode fingers are mounted in a gaseous medium that provides a damping effect counteracting relative displacement of the capacitive electrode fingers when the proof mass moves in response to an applied acceleration; at least one further fixed capacitor electrode comprising a plurality of further fixed capacitive electrode fingers extending along the sensing direction; the proof mass comprising a plurality of moveable capacitive electrode fingers extending from the proof mass along the sensing direction and arranged to interdigitate with the plurality of further fixed capacitive electrode fingers of the at least one further fixed capacitor electrode; and means for applying a voltage to the at least one further fixed capacitor electrode to apply an electrostatic force to the plurality of moveable capacitive electrode fingers that acts to pull the proof mass towards the at least one further fixed capacitor electrode and thereby reduces the first and/or second lateral spacings; wherein the least one further fixed capacitor electrode comprises a fixed capacitor electrode arranged centrally of the proof mass; and wherein the proof mass comprises a first moveable frame for the first set of interdigitated capacitive electrode fingers arranged on one side of the fixed capacitor electrode and a second moveable frame for the second set of interdigitated capacitive electrode fingers arranged on an opposite side of the fixed capacitor electrode. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A method of controlling a capacitive accelerometer comprising:
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a substantially planar proof mass mounted to a fixed substrate by flexible support legs so as to be linearly moveable in an in-plane sensing direction in response to an applied acceleration; the proof mass comprising first and second sets of moveable capacitive electrode fingers extending from the proof mass perpendicular to the sensing direction and laterally spaced in the sensing direction; first and second fixed capacitor electrodes comprising first and second sets of fixed capacitive electrode fingers extending perpendicular to the sensing direction and laterally spaced in the sensing direction; the first set of fixed capacitive electrode fingers arranged to interdigitate with the first set of moveable capacitive electrode fingers of the proof mass, with a first offset in one direction from a median line to define a first lateral spacing therebetween, and the second set of fixed capacitive electrode fingers arranged to interdigitate with the second set of moveable capacitive electrode fingers of the proof mass, with a second offset in the opposite direction from a median line to define a second lateral spacing therebetween; wherein the interdigitated capacitive electrode fingers are mounted in a gaseous medium that provides a damping effect counteracting relative displacement of the capacitive electrode fingers when the proof mass moves in response to an applied acceleration; at least one further fixed capacitor electrode comprising a plurality of further fixed capacitive electrode fingers extending along the sensing direction; and the proof mass comprising a plurality of moveable capacitive electrode fingers extending from the proof mass along the sensing direction and arranged to interdigitate with the plurality of further fixed capacitive electrode fingers of the at least one further fixed capacitor electrode; wherein the least one further fixed capacitor electrode comprises a fixed capacitor electrode arranged centrally of the proof mass; and wherein the proof mass comprises a first moveable frame for the first set of interdigitated capacitive electrode fingers arranged on one side of the fixed capacitor electrode and a second moveable frame for the second set of interdigitated capacitive electrode fingers arranged on an opposite side of the fixed capacitor electrode; the method comprising; applying a voltage to the at least one further fixed capacitor electrode to apply an electrostatic force to the plurality of moveable capacitive electrode fingers that acts to pull the proof mass towards the at least one further fixed capacitor electrode so as to reduce the first and/or second lateral spacings. - View Dependent Claims (10, 11, 12, 13)
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Specification