Closed loop temperature compensation for accelerometer current scale factor
First Claim
1. A load independent temperature compensation system for use with a force balance accelerometer that produces an output signal in response to an acceleration and which includes a magnetic circuit assembly, a servo feedback loop, and a torque circuit having a predefined impedance and a predefined resistance temperature coefficient, comprising:
- a parallel resistor, disposed in close thermal communication with both the magnetic circuit assembly and the torque circuit, and electrically connected to the torque circuit, the parallel resistor having an impedance substantially greater than the predefined impedance of the torque circuit and a resistance temperature coefficient that is larger than the predefined resistance temperature coefficient of the torque circuit, the close thermal communication of the parallel resistor with the magnetic circuit assembly and the torque circuit ensuring that the parallel resistor is substantially at the same temperature as the magnetic circuit assembly and the torque circuit so that the impedance of the parallel resistor and the predefined impedance of the torque circuit change in opposite directions in response to the temperature of the magnetic circuit assembly, thereby minimizing the effect of temperature on the output signal of the accelerometer, wherein the torque circuit comprises a torque coil, and wherein said compensation system includes a series resistor connected in series with the torque coil, the parallel resistor being connected in parallel with both the series resistor and the torque coil, and wherein the series resistor has a resistance temperature coefficient that is substantially equal to zero.
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Accused Products
Abstract
A temperature compensation system for a force balance accelerometer is disposed within a feedback loop. A series resistor (82) is connected in series with torque coils (30,80). Connected in parallel with the torque coils and the series resistor (82) is a parallel resistor (84) having a positive resistive temperature coefficient. Series resistor (82) and parallel resistor (84) are placed in close thermal communication with torque coil (30) and a magnetic circuit that includes stators (10 and 12) and permanent magnets (14). As the temperature of the accelerometer increases, less current flows through parallel resistor (84) and more current flows through the torque coil (30), thereby compensating for a reduced torque constant of torque coil that decreases with temperature, yet, enabling the resulting output current, Io, to remain constant (for a given acceleration).
24 Citations
11 Claims
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1. A load independent temperature compensation system for use with a force balance accelerometer that produces an output signal in response to an acceleration and which includes a magnetic circuit assembly, a servo feedback loop, and a torque circuit having a predefined impedance and a predefined resistance temperature coefficient, comprising:
a parallel resistor, disposed in close thermal communication with both the magnetic circuit assembly and the torque circuit, and electrically connected to the torque circuit, the parallel resistor having an impedance substantially greater than the predefined impedance of the torque circuit and a resistance temperature coefficient that is larger than the predefined resistance temperature coefficient of the torque circuit, the close thermal communication of the parallel resistor with the magnetic circuit assembly and the torque circuit ensuring that the parallel resistor is substantially at the same temperature as the magnetic circuit assembly and the torque circuit so that the impedance of the parallel resistor and the predefined impedance of the torque circuit change in opposite directions in response to the temperature of the magnetic circuit assembly, thereby minimizing the effect of temperature on the output signal of the accelerometer, wherein the torque circuit comprises a torque coil, and wherein said compensation system includes a series resistor connected in series with the torque coil, the parallel resistor being connected in parallel with both the series resistor and the torque coil, and wherein the series resistor has a resistance temperature coefficient that is substantially equal to zero. - View Dependent Claims (2)
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3. A load independent temperature compensation system for use with a force balance accelerometer that produces an output signal in response to an acceleration and which includes a magnetic circuit assembly, a servo feedback loop and a torque circuit having a predefined impedance and a predefined resistance temperature coefficient, comprising:
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a parallel resistor, disposed in close thermal communication with both the magnetic circuit assembly and the torque circuit, and electrically connected to the torque circuit, the parallel resistor having an impedance substantially greater than the predefined impedance of the torque circuit and a resistance temperature coefficient that is larger than the predefined resistance temperature coefficient of the torque circuit, the close thermal communication of the parallel resistor with the magnetic circuit assembly and the torque circuit ensuring that the parallel resistor is substantially at the same temperature as the magnetic circuit assembly and the torque circuit so that the impedance of the parallel resistor and the predefined impedance of the torque circuit change in opposite directions in response to the temperature of the magnetic circuit assembly, thereby minimizing the effect of temperature on the output signal of the accelerometer, wherein the torque circuit comprises a torque coil, and wherein said compensation system includes a series resistance connected in series with the torque coil, the parallel resistor being connected in parallel with both the series resistor and the torque coil, and wherein the resistance temperature coefficient of the series resistance varies non-linearly as a function of temperature. - View Dependent Claims (4, 5, 6)
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7. A method for temperature compensating an output signal of a force balance accelerometer that includes a torque circuit having a torque coil and a predetermined impedance and a predetermined resistance temperature coefficient, a magnetic circuit assembly, and a servo feedback loop, comprising the steps of:
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providing a parallel impedance to the torque circuit; mounting the parallel impedance in thermal communication with both the magnetic circuit assembly and the torque circuit, said parallel impedance being substantially greater than the predetermined impedance of the torque circuit and having a resistance thermal coefficient larger than the predetermined resistance temperature coefficient of the torque circuit, whereby a desired correction factor due to the parallel impedance appears in the servo feedback loop and therefore compensates for temperature errors in the accelerometer independently of any load connected to its output signal; and providing a resistance in the torque circuit in series with the torque coil and selecting the series resistance so that it has a resistance temperature coefficient substantially equal to zero and an impedance appropriate to provide the predetermined impedance for the torque circuit. - View Dependent Claims (8, 9)
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10. A method for temperature compensating an output signal of a force balance accelerometer that includes a torque circuit having a torque coil and a predetermined impedance and a predetermined resistance temperature coefficient, a magnetic circuit assembly, and a servo feedback loop, comprising the steps of:
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providing a parallel impedance to the torque circuit; mounting the parallel impedance in thermal communication with both the magnetic circuit assembly and the torque circuit, said parallel impedance being substantially greater than the predetermined impedance of the torque circuit and having a resistance thermal coefficient larger than the predetermined resistance temperature coefficient of the torque circuit, whereby a desired correction factor due to the parallel impedance appears in the servo feedback loop and therefore compensates for temperature errors in the accelerometer independently of any load connected to its output signal; and providing a resistance in the torque circuit in series with the torque coil and selecting the series resistance so that it has a resistance temperature coefficient that is non-linear, and mounting the series resistance in close thermal communication with the magnetic circuit assembly. - View Dependent Claims (11)
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Specification