Temperature compensated and self-calibrated current sensor using reference magnetic field
First Claim
1. A method to compensate for the temperature dependence and calibration drift of a current sensor comprised of a plurality of magnetic field sensors positioned around a current carrying conductor, the outputs of which are electronically combined to produce a signal representing the current flowing in said electrical conductor, where the sensitivity to magnetic fields of each sensor is proportional to the voltage of the power source that is applied to each sensor, comprising the steps of selecting a first magnetic field sensor from the plurality of magnetic field sensors having a temperature dependence of sensitivity to magnetic fields that is substantially the same as the temperature dependence of sensitivity for the plurality of magnetic field sensors, positioning a solenoidal coil proximate to first magnetic field sensor, exciting the solenoidal coil with a known electrical current, electronically processing first magnetic field sensor signal to generate an error signal that is proportional to the magnetic field created by the solenoidal coil while rejecting signals generated by other magnetic fields, and using the error signal to control a voltage regulator that generates the power source for the plurality of magnetic field sensors.
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Accused Products
Abstract
A method is described to provide temperature compensation and self-calibration of a current sensor based on a plurality of magnetic field sensors positioned around a current carrying conductor. A reference magnetic field generated within the current sensor housing is detected by the magnetic field sensors and is used to correct variations in the output signal due to temperature variations and aging.
52 Citations
12 Claims
- 1. A method to compensate for the temperature dependence and calibration drift of a current sensor comprised of a plurality of magnetic field sensors positioned around a current carrying conductor, the outputs of which are electronically combined to produce a signal representing the current flowing in said electrical conductor, where the sensitivity to magnetic fields of each sensor is proportional to the voltage of the power source that is applied to each sensor, comprising the steps of selecting a first magnetic field sensor from the plurality of magnetic field sensors having a temperature dependence of sensitivity to magnetic fields that is substantially the same as the temperature dependence of sensitivity for the plurality of magnetic field sensors, positioning a solenoidal coil proximate to first magnetic field sensor, exciting the solenoidal coil with a known electrical current, electronically processing first magnetic field sensor signal to generate an error signal that is proportional to the magnetic field created by the solenoidal coil while rejecting signals generated by other magnetic fields, and using the error signal to control a voltage regulator that generates the power source for the plurality of magnetic field sensors.
- 4. A device for measuring electric current comprised of a plurality of magnetic field sensors positioned around a current carrying conductor, the outputs of which are electronically combined to produce a signal representing the current flowing in said electrical conductor, where each sensor is sensitive to one vector component of the magnetic field generated by the electric current, where the sensors are positioned along one or more continuous closed paths encircling the conductor, where the sensors have substantially identical sensitivity along each closed path, where the sensors are equally spaced along the length of each closed path, where the vector direction of sensitivity for each sensor is oriented to be tangential with the closed path at each sensor location, where the sensitivity to magnetic fields of each sensor is proportional to the voltage of the power source that is applied to each sensor, where a first magnetic field sensor selected from the plurality of magnetic field sensors has a temperature dependence of sensitivity to magnetic fields that is substantially the same as the temperature dependence of sensitivity for the plurality of magnetic field sensors, where a solenoidal coil is positioned proximate to first magnetic field sensor, where the solenoidal coil is excited with a known electrical current, where first magnetic field sensor signal is electronically processed to generate an error signal that is proportional to the magnetic field created by the solenoidal coil while rejecting signals generated by other magnetic fields, and where the error signal is used to control a voltage regulator that generates the power source for the plurality of magnetic field sensors.
- 7. A method to compensate for the temperature dependence and calibration drift of a current sensor comprised of a plurality of magnetic field sensors positioned around a current carrying conductor, the outputs of which are electronically combined to produce a signal representing the current flowing in said electrical conductor, where the sensitivity to magnetic fields of each sensor is proportional to the voltage of the power source that is applied to each sensor, comprising the steps of selecting a first magnetic field sensor from the plurality of magnetic field sensors having a temperature dependence of sensitivity to magnetic fields that is substantially the same as the temperature dependence of sensitivity for the plurality of magnetic field sensors, positioning a permanent magnet proximate to first magnetic field sensor, electronically processing first magnetic field sensor signal to generate an error signal that is proportional to the magnetic field created by the permanent magnet while rejecting signals generated by other magnetic fields, and using the error signal to control a voltage regulator that generates the power source for the plurality of magnetic field sensors.
- 10. A device for measuring electric current comprised of a plurality of magnetic field sensors positioned around a current carrying conductor, the outputs of which are electronically combined to produce a signal representing the current flowing in said electrical conductor, where each sensor is sensitive to one vector component of the magnetic field generated by the electric current, where the sensors are positioned along one or more continuous closed paths encircling the conductor, where the sensors have substantially identical sensitivity along each closed path, where the sensors are equally spaced along the length of each closed path, where the vector direction of sensitivity for each sensor is oriented to be tangential with the closed path at each sensor location, where the sensitivity to magnetic fields of each sensor is proportional to the voltage of the power source that is applied to each sensor, where a first magnetic field sensor selected from the plurality of magnetic field sensors has a temperature dependence of sensitivity to magnetic fields that is substantially the same as the temperature dependence of sensitivity for the plurality of magnetic field sensors, where a permanent magnet is positioned proximate to first magnetic field sensor, where first magnetic field sensor signal is electronically processed to generate an error signal that is proportional to the magnetic field created by the permanent magnet while rejecting signals generated by other magnetic fields, and where the error signal is used to control a voltage regulator that generates the power source for the plurality of magnetic field sensors.
Specification