MAGNETIC NULL ACCELEROMETER
1 Assignment
0 Petitions
Accused Products
Abstract
An accelerometer system includes a capacitor plate fixed within a housing and a flexure plate positioned substantially parallel to the capacitor plate a distance therefrom. The distance varies in response to acceleration forces acting upon the flexure plate such that the flexure plate and the capacitor plate generate a capacitance signal. A magnet is coupled to the flexure plate and generates a magnetic field, which moves as the flexure plate flexes. A coil winding around the flexure plate generates a second magnetic field as a function of capacitance signal, thus opposing the flexure plate magnetic field, and thereby returning the flexure plate to a null position.
70 Citations
50 Claims
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1-39. -39. (canceled)
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40. A magnetic null accelerometer comprising:
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first and second capacitor plates arranged in parallel spaced apart a given distance from each other; a flexure plate mounted in between said first and second capacitor plates and capable of flexing in response to acceleration forces applied thereon, said flexure plate having a first side facing said first capacitor plate for forming a first capacitor generating a first capacitance signal based on its distance from said first capacitor plate, and having a second side facing said second capacitor plate for forming a second capacitor generating a second capacitance signal based on its distance from said second capacitor plate, and said flexure plate having a null position between said first and second capacitor plates at which the first and second capacitance signals are equal; a capacitance measuring circuit for measuring the first and second capacitance signals and detecting a difference between them as an indicator of offset of said flexure plate from its null position to a flexed position under acceleration forces; a magnet coupled to said flexure plate between said first and second capacitor plates, and a current-controlled coil having a single windings receiving a single control current for generating a magnetic force opposing the magnetic field of the magnet when said flexure plate is in a flexed position so as to restore said flexure plate to its null position; and a compensation circuit for generating a single control current in response to the difference between the first and second capacitance signals measured by said capacitance measuring circuit and for applying the corresponding single control current to said coil so as to restore said flexure plate to its null position. - View Dependent Claims (41, 42, 43)
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44. A magnetic null accelerometer control circuit comprising:
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a first capacitor plate spaced apart a distance from a flexure plate which is capable of flexing in response to acceleration forces applied thereon, said flexure plate having a first side facing said first capacitor and forming a first capacitor for generating a first capacitance signal based on its distance from said first capacitor plate, and said flexure plate having a null position relative to said first capacitor plate; a capacitance measuring circuit for measuring the first capacitance signal and detecting a difference indicator of offset of said flexure plate from its null position to a flexed position under acceleration forces; a magnet coupled to said flexure plate, and a current-controlled coil having a single windings receiving a single control current for generating a magnetic force opposing the magnetic field of the magnet when said flexure plate is in a flexed position so as to restore said flexure plate to its null position; and a compensation circuit for generating a single control current in response to the difference indicator measured by said capacitance measuring circuit and for applying the corresponding single control current to said coil so as to restore said flexure plate to its null position. - View Dependent Claims (45, 46, 47, 48)
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49. A method for operating a flexure plate accelerometer comprising:
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providing a first capacitor plate spaced apart a distance from a flexure plate which is capable of flexing in response to acceleration forces applied thereon, providing a first side of the flexure plate facing the first capacitor plate and forming a first capacitor therewith for generating a first capacitance signal based on its distance from the first capacitor plate, wherein the flexure plate has a null position relative to the first capacitor plate; measuring the first capacitance signal and detecting a difference indicator of offset of the flexure plate from its null position to a flexed position under acceleration forces; providing a magnet that is coupled to the flexure plate, and a current-controlled coil having a single winding receiving a single control current for generating a magnetic force opposing the magnetic field of the magnet when the flexure plate is in a flexed position so as to restore the flexure plate to its null position; and generating a single control current in response to the difference indicator measured as an offset of the flexure plate from its null position to a flexed position under acceleration forces, and applying it to the coil to drive the magnet so as to restore the flexure plate to its null position. - View Dependent Claims (50)
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Specification