A power supply control device controls power supply via a switch by causing a drive circuit to turn on and off the switch. A first resistance is disposed on a path of a current flowing via the switch. A differential amplifier outputs a voltage corresponding to a value of a voltage between two ends of the first resistance. A first capacitor is connected between a point midway on a path of power supply to the differential amplifier and an upstream end of the first resistance. A second capacitor is connected between a point midway on the path of power supply and a downstream end of the first resistance.

Apparatus and associated methods relate to a peaking module fabricated on a semiconductor substrate including a follower circuit driving a series peaking circuit-branch, the module configured to extend the bandwidth of a track-and-hold circuit. In an illustrative example, the series peaking circuit-branch may include an inductive element. One or more tracks on a metal interconnect above the semiconductor substrate may form the inductive element, for example. In some examples, one or more peaking modules may be combined creating a customized frequency response. In some examples, one or more combined peaking modules may be adjusted by a controller providing dynamic frequency response customization during operation. The follower circuits may employ constant current biasing and/or constant-g.sub.m biasing to provide substantial immunity to process, temperature and voltage variations, for example. Various implementations of series peaking circuit-branch pre-emphasis may advantageously extend overall bandwidth of various circuits (e.g., high-speed track-and-hold circuits).

Techniques for monitoring a distortion signal of a power amplifier circuit, where the output of a distortion monitoring circuit includes little or no fundamental signal and closely represents the actual distortion of the amplifier circuit of a wired communications system. The power amplifier circuit can generate a distortion feedback signal that does not affect the power amplifier's output power capability, e.g., no inherent loss in the fundamental output of the amplifier. That is, using a distortion monitor circuit, the power amplifier circuit can resolve a distortion feedback signal from the intended output signal of the output power amplifier circuit.

A signal distribution circuit including an equalization circuit, a signal distribution part, an operational amplifying circuit, a feedback circuit, and a time sequence circuit. The equalization circuit is configured to collect an initial broadband signal. The signal distribution part is configured to distribute a first-stage broadband signal resulting from amplitude attenuation process to obtain a plurality of same second-stage broadband signals. The operational amplifying circuit is configured to perform amplification processing on the second-stage broadband signal obtained after distribution to obtain a third-stage broadband signal. The feedback circuit is configured to feedback the third-stage broadband signal to the equalization circuit. The time sequence circuit is configured to adjust an amplification gain of the third-stage broadband signal, and transmit the third-stage broadband signal to an analog to digital converter.

A method and apparatus for transmitting a communication signal through a dual-mode power amplifier may include amplifying a communication signal by a first amplifier and/or a second amplifier of the dual-mode power amplifier based on a desired transmit output power. The output of the first amplifier may be selectively coupled through a configurable inductive coupler to an antenna.

An envelope tracking system is employed in a power amplification module that supports multiple frequency bands. The power amplification module includes multiple power amplification circuits, each of which includes: a first transformer to which a radio frequency signal is input; a differential amplification circuit, in which a first radio frequency signal output from transformer is input to a control electrode and in which a second radio frequency signal output from the transformer is input to a control electrode, the differential amplification circuit outputting an amplified signal obtained by amplifying a difference between the first and second radio frequency signals; and a second transformer for supplying, to the first differential amplification circuit, power-supply voltage varying according to the amplitude of the radio frequency signal and to which the first amplified signal is input.

A circuit may include first and second input nodes, first and second output nodes, first and second intermediate nodes, first and second resistances, a first amplification transistor coupled to the first input node, the first resistance, and the first intermediate node and a second amplification transistor coupled to the second input node, the second resistance, and the second intermediate node. The circuit may also include a first active device coupled to the first output node and the first intermediate node, a second active device coupled to the second output node and the second intermediate node, a first output transistor coupled to the first output node and configured to conduct based on a second intermediate signal on the second intermediate node, and a second output transistor coupled to the second output node and configured to conduct based on a first intermediate signal on the first intermediate node.

A circuit includes an electrical gain element, a variable reactance element, and a controller. The electrical gain element is arranged to receive and change an amplitude of a signal over a set frequency range. The variable reactance element is connected to the electrical gain element. The controller is configured to control the variable reactance element to have a reactance such that the electrical gain element has a set gain slope as a function of signal frequency over the set frequency range.

An amplifier includes two input terminals to receive a differential, two-tone transmission signal; two output terminals; a coil having terminals connected with the input terminals respectively, and a center tap; a first transistor having the gate connected with one terminal of the coil, and the output terminal connected with one output terminal; a second transistor having the gate connected with the other terminal of the coil, and the output terminal connected with the other output terminal; a diode having a terminal connected with the center tap; and a bias circuit connected with the other terminal of the diode to output a gate voltage to turn on the first and second transistors. The diode adjusts the terminal voltage depending on a signal level of a double harmonic wave of the transmission signal supplied to the terminal of the diode from the center tap.

An apparatus is disclosed for implementing a clamping circuit with an interstage matching network or between two amplifier stages to provide power clamping. In example aspects, the apparatus includes an amplifier circuit having an input port and an output port. The amplifier circuit includes a driver amplifier, an interstage matching network, a power amplifier, and a clamping circuit. The driver amplifier includes a driver amplifier output and is coupled between the input port and the output port. The power amplifier includes a power amplifier input and is coupled between the driver amplifier output and the output port. The interstage matching network is coupled between the driver amplifier output and the power amplifier input. The clamping circuit includes a transistor and a resistor coupled thereto. The clamping circuit is coupled to the interstage matching network via a node that is coupled between the driver amplifier output and the power amplifier input.