Chopper-stabilized amplifier and magnetic field sensor

Abstract

A chopper-stabilized amplifier has switching networks arranged to support a high frequency clocking signal and to provide a high common mode rejection and a high rejection of an offset component of an input signal. A magnetic field sensor includes a Hall effect element coupled to a modulation circuit. The modulation circuit provides a signal to the chopper-stabilized amplifier. The chopper-stabilized amplifier provides an output signal to a low pass filter, which provides an output signal from the magnetic field sensor.

Description

CROSS REFERENCE TO RELATED APPLICATIONS[0001]Not Applicable.STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH[0002]Not Applicable.FIELD OF THE INVENTION[0003]This invention relates generally to chopper-stabilized amplifiers and to magnetic field sensors that use chopper-stabilized amplifiers and, more particularly, to a chopper-stabilized amplifier that can reduce an offset component of an input signal and provide improved common mode rejection while supporting a relatively high switching frequency, and to a magnetic field sensor that uses such a type of chopper-stabilized amplifier.BACKGROUND OF THE INVENTION[0004]As is known, some types of analog electronic signals include both a signal component and an offset component. The offset component is usually an undesirable DC component, while the signal component can be an AC component that usually carries information used by an electronic system that receives the electronic signal. It will be recognized that, if such an electronic signa...

AI Technical Summary

Benefits of technology

The patent describes a magnetic field sensor that includes a Hall effect element and a chopper-stabilized amplifier. The sensor has a modulation circuit that modulates the magnetic field signal component to provide a modulated signal with an unmodulated offset component. The chopper-stabilized amplifier is responsible for amplifying the modulated signal and reducing the offset component. The sensor also includes a feedback circuit or a second switching network to generate switched feedback signals. The technical effect of this invention is to provide a more accurate and reliable magnetic field sensor with reduced offset components and improved performance.

Problems solved by technology

It will be recognized that, if such an electronic signal is received by and amplified by an amplifier, the amplified offset component might saturate the amplifier or cause other undesirable effects upon the electronic system receiving the electronic signal.

Also, an amplifier itself has an input offset voltage, which, if greatly amplified, can saturate the amplifier or another amplifier or cause undesirable effects upon the system.

A higher switching frequency tends to result in an ability to use a low pass filter with a wider passband, which further tends to result in the magnetic field sensor having a faster response time.

As the low pass filter passband is reduced to reduce the ripple, the response time of the magnetic field sensor increases, which is undesirable.

For example, some conventional chopper-stabilized amplifiers require a relatively low switching frequency, and therefore, as described above, a low pass filter with a relatively narrow passband and a resulting relatively slow response time.

For another example, some conventional chopper-stabilized amplifiers suffer from having a relatively low common mode rejection and / or a relatively low rejection of the offset component.

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