An apparatus for performing baseline wander correction is provided. The apparatus may include: a plurality of filters, a common mode voltage generator, and a compensation circuit. The plurality of filters may filter a set of input signals to generate a set of differential signals, the common mode voltage generator may generate a common mode voltage between the set of differential signals, and the compensation circuit may perform compensation related to baseline wander correction on the set of differential signals. Multiple current paths of the compensation circuit are associated with each other. Through a first current path and a second current path within the current paths, the compensation circuit may perform charge or discharge control on a first capacitor and a second capacitor within the plurality of filters to dynamically adjust compensation amounts of the compensation, to reduce or eliminate a baseline wander effect of the set of differential signals.

A multiple-gain transconductance amplifier circuit is presented. It is developed by utilizing programmable gain source-coupling differential pair output stage forming multiple-gain transconductance amplifier outputs. A reconfigurable n.sup.th-order filter based on a multi-gain transconductance amplifier where the multi-gain transconductance amplifier includes a linear voltage-to-current converter and a programmable current-folding output stage was implemented. The filter achieves independent programmability while still using a single active device per pole. Further, the proposed multiple-gain transconductance amplifier can be employed to design poly phase filters and transconductance amplifier cell for an amplifier-based low-dropout regulator.

An amplification device having a cascode structure includes an amplification circuit including a first transistor and a second transistor, cascode-connected to each other and receiving an operating voltage to amplify an input signal; a first bias circuit generating a first bias voltage and supplying the first bias voltage to the first transistor; and a second bias circuit generating a second bias voltage based on a control voltage and the operating voltage and supplying the second bias voltage to the second transistor.

Methods, circuits, and apparatuses that provide Buffer Amplifier, containing Amplifiers and Buffer Drivers, one or more of the following: ultra low power Buffer Amplifier, capable of having high gain, low noise, high speed, near rail-to-rail input-output voltage span, high sink-source current drive capability for an external load, and able to operate at low power supply voltages. Methods, circuits, and apparatuses that provide regulated cascode (RGC) current mirrors (CM) capable of operating at low power supply and having wide input-output voltage spans.

A comparator includes a folded cascode stage having positive and negative outputs. The folded cascode stage includes: a common-mode voltage regulation circuit that includes resistive elements that are respectively situated between each of the outputs and a common-mode node. A compensation circuit is configured to regulate a difference between the voltages on the outputs, and is configured to generate a constant and continuous compensation current in the two resistive elements. A hysteresis circuit is configured to offset voltages on the outputs, and to generate a hysteresis current in the two resistive elements.

An amplifier includes an input stage, a folded cascode stage, and a class AB output stage. The folded cascode stage is coupled to the input stage. The class AB output stage is coupled to the folded cascode stage. The class AB output stage includes a high-side output transistor, a low-side output transistor, and a high-side feedback circuit that is coupled to the high-side output transistor. The high-side feedback circuit includes a high-side sense transistor and a high-side feedback transistor. The high-side sense transistor includes a control terminal that is coupled to a control terminal of the high-side output transistor. The high-side feedback transistor is coupled to an output of the high-side sense transistor and to the folded cascode stage. A first output of the folded cascode stage is coupled to the control terminal of the high-side sense transistor and to the control terminal of the high-side output transistor.

An apparatus for performing baseline wander correction is provided. The apparatus may include: a plurality of filters, a common mode voltage generator, and a compensation circuit. The plurality of filters may filter a set of input signals to generate a set of differential signals, the common mode voltage generator may generate a common mode voltage between the set of differential signals, and the compensation circuit may perform compensation related to baseline wander correction on the set of differential signals. Multiple current paths of the compensation circuit are associated with each other. Through a first current path and a second current path within the current paths, the compensation circuit may perform charge or discharge control on a first capacitor and a second capacitor within the plurality of filters to dynamically adjust compensation amounts of the compensation, to reduce or eliminate a baseline wander effect of the set of differential signals.

Provided are a transmitting device connected to a receiving device via a channel and the receiving device connected to the transmitting device via a channel. The transmitting device connected to a receiving device includes: a transmitter connected to the channel via an output node and configured to transmit, via the channel, a transmission signal to the receiving device, the transmitter having a transmission impedance associated therewith that is variable; and a monitoring device configured to detect a channel impedance of the channel and a receiving impedance of the receiving device by monitoring a voltage level of the output node, the monitoring device configured to set the transmission impedance based on the channel impedance and the receiving impedance.

The amplifier includes an input circuit configured to convert an input signal into a current; an output circuit comprising at least one switching element for reducing a voltage change of an output end of the input circuit and configured to provide an output signal; and a biasing circuit connected to the at least one switching element to form a feedback loop for reducing the voltage change of the output end of the input circuit.

There are an amplifier circuit which includes a first current source that is connected to a power supply line to which a first electric potential is supplied, a differential input circuit that is connected between the first current source and a first node and configured to receive a differential input signal, a second current source that is connected between a power supply line to which a second electric potential is supplied and the first node, and a load circuit that is connected between a power supply line to which the first electric potential is supplied and a second node, and an inductor circuit is further connected between the first node and the second node. Thereby, the amplifier circuit achieves both lower voltage and linearity.