An operational amplifier includes a first output transistor and a second output transistor connected in series between two power nodes, the second output transistor having a semiconductor type opposite to the first output transistor, the first output transistor and the second output transistor being electrically coupled at an output node, and gates of the first output transistor and the second output transistor being connected to a first drive node and a second drive node respectively; and a decoupling capacitor circuit electrically connected between the first drive node and the second drive node.

Provided is an interpolation operational amplifier circuit, including: at least two sets of differential input pair transistors, each differential input pair transistor including first and second transistors, wherein base terminals of the first and second transistors are electrically connected to serve as a base terminal of the differential input pair transistor, and source electrodes of the first and second transistors are electrically connected to serve as a source electrode of the differential input pair transistor; and a voltage control unit electrically connected to the base terminal and source electrode of the differential input pair transistor, and configured to control a voltage of the base terminal of the P-type differential input pair transistor to be smaller than the first power supply voltage, and/or to control a voltage of the base terminal of the N-type differential input pair transistor to be larger than the second power supply voltage.

An operational transconductance amplifier, that may include a first differential pair that comprises a first transistor and a second transistor that are coupled to each other at a certain node; wherein the first differential pair is configured to convert a differential input voltage to first and second output currents; a current source that is coupled to the certain node and may include an adjustable current sources; and a feedback unit that is coupled to the certain node and is configured to (a) receive the differential input voltage, and maintain a voltage of the certain node substantially fixed regardless of changes in the differential input voltage.

Disclosed herein is an operational amplifier including a non-inverting input terminal, an inverting input terminal, a P-type metal oxide semiconductor input differential pair, a first input tail current source, an N-type metal oxide semiconductor input differential pair, a second input tail current source, an output stage, a first correction circuit, and a second correction circuit. The first correction circuit and the second correction circuit operate over an operation region of the P-type metal oxide semiconductor input differential pair, an operation region of the N-type metal oxide semiconductor input differential pair, and a transition region in which both the P-type metal oxide semiconductor input differential pair and the N-type metal oxide semiconductor input differential pair operate.

An operational transconductance amplifier, that may include a first differential pair that comprises a first transistor and a second transistor that are coupled to each other at a certain node; wherein the first differential pair is configured to convert a differential input voltage to first and second output currents; a current source that is coupled to the certain node and may include an adjustable current sources; and a feedback unit that is coupled to the certain node and is configured to (a) receive the differential input voltage, and maintain a voltage of the certain node substantially fixed regardless of changes in the differential input voltage.

Provided is an interpolation operational amplifier circuit, including: at least two sets of differential input pair transistors, each differential input pair transistor including first and second transistors, wherein base terminals of the first and second transistors are electrically connected to serve as a base terminal of the differential input pair transistor, and source electrodes of the first and second transistors are electrically connected to serve as a source electrode of the differential input pair transistor; and a voltage control unit electrically connected to the base terminal and source electrode of the differential input pair transistor, and configured to control a voltage of the base terminal of the P-type differential input pair transistor to be smaller than the first power supply voltage, and/or to control a voltage of the base terminal of the N-type differential input pair transistor to be larger than the second power supply voltage.

A method for initializing a phase adder circuit including a multiplier circuit with its two inputs receiving signals of frequency f.sub.o, a mixer circuit, an amplifier circuit, a low pass loop filter, and a voltage controlled oscillator (VCO), the method including: during a first phase, determining a reference voltage which when applied to the VCO causes it to produce a signal having a frequency of nf.sub.0; during a second phase, supplying a signal of frequency nf.sub.o to a first input of the mixer and a signal of frequency (nf.sub.o+Δf) to a second input of the mixer; and determining an adjustment signal which when applied to the amplifier circuit causes the amplifier circuit to output a signal having a DC component equal to the reference voltage; and during a third phase, forming a primary phase locked loop (PLL) circuit including the mixer, the amplifier circuit, the low pass loop filter and the VCO; and applying the adjustment signal to the amplifier circuit.

An output stage circuit of an operational amplifier, the operational amplifier, and a signal amplifying method applied to the operational amplifier are provided. The output stage circuit includes an inverting circuit and a compensation module. The inverting circuit is electrically connected to a gain stage circuit of the operational amplifier. The inverting circuit generates an output signal of the operational amplifier. The compensation module includes a first compensation circuit, including a first current providing path and a first suppression activation circuit. The first current providing path provides a first compensation current. The first suppression activation circuit conducts the first compensation current to the inverting circuit if a first compensation condition related to a first gain stage signal generated by the gain stage circuit is satisfied. Variation of the output signal is suppressed because of the first compensation current.

An operational amplifier includes a single-stage amplifier and a current controller. The single-stage amplifier receives an input signal, and amplifies the input signal to generate an output signal, wherein the single-stage amplifier includes a voltage controlled current source circuit that operates in response to a bias voltage input. The current controller receives the input signal, and generates the bias voltage input according to the input signal.

A half-power buffer amplifier is disclosed. The amplifier includes an amplification unit configured to differentially amplify differential input signals, the amplification unit including nodes configured to output differentially amplified first to fourth output signals, a first output buffer unit including first and second transistors, and an output node to which the first and second transistors are connected, a second output buffer unit including third and fourth transistors, wherein the third and fourth transistors are connected to the output node, a first control switch between the first output node and the second transistor and controlled by a polarity control signal, and a second control switch between the second output node and the third transistor and controlled by a complement of the polarity control signal.