Adaptive biasing circuits for input differential pairs of a buffer or an amplifier adapt to autozero currents for discrete pair selection or continuous pair selection. The adaptive biasing circuits include a multistage device including current source and follower devices with a plurality of switches for a two-phase operation: autozero and amplifying phases. During an autozero phase, input differential pairs are isolated from subsequent stages and biasing currents are determined for autozeroing of input offset voltages. During an amplifying phase, both input differential pairs can be coupled to subsequent stages for continuous selection or a selected input differential pair can be coupled to subsequent stages for discrete selection.

Techniques and apparatus for supplying power with offset voltage generation are provided. One example power supply circuit generally includes a first transistor including a source coupled to an input voltage (Vin) node and a drain coupled to an output voltage (Vout) node, a second transistor including a drain coupled to a gate of the first transistor, a third transistor including a drain coupled to the drain of the second transistor and to the gate of the first transistor, where a source of the third transistor is coupled to a reference potential node of the power supply circuit, an amplifier including a first input coupled to a reference voltage (Vref) node and an output coupled to a gate of the third transistor, and a voltage offset circuit coupled between the gate of the first transistor and a gate of the second transistor.

Independent control loops for mitigating positive and negative mismatch in differential amplifiers are provided. A method includes comparing a first voltage measured at a positive side output of an emitter follower with a reference voltage, resulting in a first voltage difference. The method also includes comparing a second voltage measured at a negative-side output of the emitter follower with the reference voltage, resulting in a second voltage difference. In addition, the method includes independently controlling the positive side and the negative side of the differential amplifier based on the first voltage difference and the second voltage difference.

A preamplifier includes an operational transconductance amplifier, a first-type metal-oxide-semiconductor (MOS) transistor have a gate electrically coupled to the OTA output; a first second-type MOS transistor; a second second-type MOS transistor electrically connected in parallel with the first second-type MOS transistor; a first load resistor electrically connected in series with a drain of the first second-type MOS transistor that has a first output voltage; a second load resistor electrically connected in series with a drain of the second second-type MOS transistor that has a second output voltage; a tail node electrically connected to a source of the first second-type MOS transistor, a source of the second second-type MOS transistor, and a drain of a third second-type MOS transistor; a common-mode feedback circuit electrically coupled to the first and second output voltages and to a first OTA input; and a reference voltage electrically coupled to a second OTA input.

Independent control loops for mitigating positive and negative mismatch in differential amplifiers are provided. A method includes comparing a first voltage measured at a positive side output of an emitter follower with a reference voltage, resulting in a first voltage difference. The method also includes comparing a second voltage measured at a negative-side output of the emitter follower with the reference voltage, resulting in a second voltage difference. In addition, the method includes independently controlling the positive side and the negative side of the differential amplifier based on the first voltage difference and the second voltage difference.

The present disclosure relates to an optical sensing module, a system and a method for operating the optical sensing system. The optical sensing module includes a light emitter that emits a sensing light in a specific wavelength range and a photodiode unit. The photodiode unit includes a first photodiode used to sense a first wavelength light, a second photodiode used to sense a second wavelength light, and a third photodiode used to sense a third wavelength light. The optical sensing module implements a proximity sensor by operations of the second photodiode and the third photodiode, or a biometric sensor by operations of the first photodiode, the second photodiode, and the third photodiode. The photodiode unit receives a reflected light from an object to be detected so as to determine if the object is proximal, and then determine whether or not the proximal object is human skin.