A chopper-stabilized current feedback amplifier includes an input buffer having a non-inverting input and an inverting input. A first group of chopper circuits modulate current at the non-inverting and inverting inputs. The current feedback amplifier further includes a plurality of current mirrors coupled to the input buffer. A second group of chopper circuits modulate current in the current mirrors. The current feedback amplifier also includes phase detector circuitry coupled to the current mirrors and configured to detect a transition current in the current mirrors. The current feedback amplifier also includes a switched capacitor filter having an input coupled to the current mirrors. The switched capacitor filter is turned OFF responsive to the detection of the transition current by the phase detector circuitry. The current feedback amplifier also includes an output stage having an input coupled to the switched capacitor filter and is configured to produce an output signal.

Low noise voltage generation circuitry includes a voltage source, a low-pass filter with one or more filter stages, and an amplifier selectively coupled to the filter stages. Each filter stage includes a resistor and a pair of capacitors of equal capacitance. The amplifier has an input selectively coupled to an output port of the voltage generation circuitry and has an output selectively coupled to the pair of capacitors in each filter stage. During a sensing phase, the amplifier senses the voltage at the output port. During a first charging phase, the amplifier has a first polarity and charges one of the pair of capacitors in each filter stage. During a second charging phase, the amplifier has a second polarity and charges another one of the pair of capacitors in each filter stage. During a final phase, the pair of capacitors within each filter stage are shorted together to cancel out an amplifier offset while the output port instantaneously settles to the target voltage.

Low noise voltage generation circuitry includes a voltage source, a low-pass filter with one or more filter stages, and an amplifier selectively coupled to the filter stages. Each filter stage includes a resistor and a pair of capacitors of equal capacitance. The amplifier has an input selectively coupled to an output port of the voltage generation circuitry and has an output selectively coupled to the pair of capacitors in each filter stage. During a sensing phase, the amplifier senses the voltage at the output port. During a first charging phase, the amplifier has a first polarity and charges one of the pair of capacitors in each filter stage. During a second charging phase, the amplifier has a second polarity and charges another one of the pair of capacitors in each filter stage. During a final phase, the pair of capacitors within each filter stage are shorted together to cancel out an amplifier offset while the output port instantaneously settles to the target voltage.

A semiconductor device includes a signal input circuit configured to select one of the plurality of differential sensor signals according to a channel selection signal; an amplifier circuit configured to amplify an output of the signal input circuit; and an analog-to-digital converter (ADC) configured to convert an output of the amplifier circuit into a digital value, wherein each of the plurality of sensor signals is a differential signals and the signal input circuit changes polarity of an output signal thereof according to a first chopping signal, and wherein the ADC includes a delta-sigma modulator configured to generate a bit stream from an output of the amplifier circuit; an output chopping circuit configured to adjust phase of the bit stream according to the first chopping signal; and a filter configured to filter an output of the output chopping circuit and to output the digital value.

A sensing circuit of a display device is provided. The sensing circuit includes a chopper circuit, a first operational amplifier and a filter. The chopper circuit is configured to receive a sensing input signal of the display device and modulate the sensing input signal. The first operational amplifier is coupled to the chopper circuit. The first operational amplifier is configured to receive the modulated sensing input signal and output the modulated sensing input signal to the chopper circuit. The chopper circuit is further configured to demodulate the modulated sensing input signal from the first operational amplifier and output the demodulated sensing input signal. The filter is coupled to the chopper circuit. The filter is configured to filter the demodulated sensing input signal from the chopper circuit and output the filtered sensing input signal as a sensing output signal. A source driver including the sensing circuit is also provided.

A sensing circuit of a display device is provided. The sensing circuit includes a chopper circuit, a first operational amplifier and a filter. The chopper circuit is configured to receive a sensing input signal of the display device and modulate the sensing input signal. The first operational amplifier is coupled to the chopper circuit. The first operational amplifier is configured to receive the modulated sensing input signal and output the modulated sensing input signal to the chopper circuit. The chopper circuit is further configured to demodulate the modulated sensing input signal from the first operational amplifier and output the demodulated sensing input signal. The filter is coupled to the chopper circuit. The filter is configured to filter the demodulated sensing input signal from the chopper circuit and output the filtered sensing input signal as a sensing output signal. A source driver including the sensing circuit is also provided.

An apparatus measures a speaker impedance. A DAC converts a known digital input signal to an audio frequency first analog voltage signal. Resistors with known resistance attenuate the first analog voltage signal to generate a current. The known resistance effectively determines the current because the known resistance is high relative to the speaker impedance. The current is sourced into the speaker to generate a second analog voltage signal. The known resistance is sufficiently high to cause the second analog voltage signal to be inaudible as transduced by the speaker. An amplifier amplifies the second analog voltage signal with a known gain to generate a third analog voltage signal. An ADC converts the third analog voltage signal to a digital output signal. A processing element calculates the impedance of the speaker proportional to the digital output signal based on the known digital input signal, the known resistance, and the known gain.

A system includes a pixel that emits light based on a signal provided to the pixel. The system may also include a buffer circuit having a differential pair stage, a cascade stage, and an output stage. The differential pair stage may receive a common mode voltage signal via a first switch in response to the first switch receiving a first signal that causes the first switch to close. The differential pair stage may couple a capacitor to the output stage via a second switch that operate based on a second signal, such that the capacitor reduces an offset provided by one or more circuit components in the differential pair stage, the cascade stage, the output stage, or any combination thereof. The differential pair stage may output the common mode voltage to the pixel via the output stage in response to the first signal being present.

A system has an output and receives an input signal. An operational amplifier has an input, an output and an offset at the input. A switched capacitor network samples the input signal at a switched capacitor frequency. An autozeroing capacitor connected to the input of the operational amplifier captures the offset during an offset capture interval according to an autozeroing frequency. Chopping and autozeroing switches, connected between the autozeroing capacitor and the switched capacitor network, chop the sampled input signal according to a chopping frequency and autozero the captured offset according to the autozeroing frequency. De-chopping switches, connected between the output of the operational amplifier and the output of the system, operate on the output of the operational amplifier at the chopping frequency to chop the autozeroed captured offset and de-chop the chopped sampled input signal processed by the operational amplifier.

In an embodiment, a differential buffer may include a first input stage that compares a non-inverting portion of an input signal alternately to a non-inverting portion of an output and to an inverting portion of the output. Another embodiment of the differential buffer may also include a second input stage that compares the inverting portion of the input signal alternately to the inverting portion of the output signal and to the non-inverting portion of the output signal. Other embodiments of the differential buffer may include a feedback chopper switch that transfers the non-inverting portion of the output signal and the inverting portion of the output signal to the first input stage and to the second input stage.