An amplifier circuit is provided that includes an amplifier having a signal input and a signal output, the amplifier being configured to produce an amplified signal at the signal output, a feedback path coupled between the signal output and the signal input, and an amplifier linearity boost circuit positioned in the feedback path. The amplifier linearity boost circuit includes a non-linear current generator and a phase-shifting circuit, the non-linear current generator being configured to provide a non-linear current based on the amplified signal, and the phase-shifting circuit being configured to adjust a phase of the non-linear current to reduce an intermodulation distortion of the amplified signal.

An amplifier circuit is provided that includes an amplifier having a signal input and a signal output, the amplifier being configured to produce an amplified signal at the signal output, a feedback path coupled between the signal output and the signal input, and an amplifier linearity boost circuit positioned in the feedback path. The amplifier linearity boost circuit includes a non-linear current generator and a phase-shifting circuit, the non-linear current generator being configured to provide a non-linear current based on the amplified signal, and the phase-shifting circuit being configured to adjust a phase of the non-linear current to reduce an intermodulation distortion of the amplified signal.

A switching amplifier circuit (200) connected to drive an impedance-based output load (230) includes high side and low side switches (201-204) configured and connected to connect first and second supply voltage lines to first and second output nodes (ANTP, ANTN) in response to gating control signals, and also includes an output current sensing circuit for measuring a current through the output load with a current sensing resistor (Rs) connected between the second supply voltage line and a source of one or more split gate-source switching transistors (203C) in the low side gate-source switching transistor, where a voltage sense circuit connected across the current sensing resistor is configured to sample a voltage across the current sensing resistor for measuring a sense current at the current sensing resistor.

Amplification with post-distortion compensation is disclosed. In an example aspect, an apparatus includes a voltage rail and a cascode amplifier. The cascode amplifier includes an amplification node, a cascode node, and a common-source node. The cascode amplifier also includes at least one cascode transistor, an input transistor, and a compensation transistor. The cascode transistor is coupled between the amplification node and the cascode node. The input transistor is coupled between the cascode node and the common-source node. The compensation transistor is coupled between the voltage rail and the cascode node.

Amplification with post-distortion compensation is disclosed. In an example aspect, an apparatus includes a voltage rail and a cascode amplifier. The cascode amplifier includes an amplification node, a cascode node, and a common-source node. The cascode amplifier also includes at least one cascode transistor, an input transistor, and a compensation transistor. The cascode transistor is coupled between the amplification node and the cascode node. The input transistor is coupled between the cascode node and the common-source node. The compensation transistor is coupled between the voltage rail and the cascode node.

A Doherty amplifier is disclosed with a main amplifier having a main input in communication with a radio frequency (RF) signal input and a main output in communication with a RF signal output. Also included is a peaking amplifier having a peak input in communication with the RF signal input and a peak output in communication with the RF signal input. Further included is main neutralization circuitry having a main neutralization input in communication with the peak input and a main neutralization output in communication with the main input, wherein the main neutralization circuitry is configured to inject a main neutralization signal into the main input such that the main neutralization signal is 18010% out of phase and equal in amplitude to within 10% of a main parasitic feedback signal passed from the main output to the main input by way of a main parasitic feedback capacitance.

A Doherty amplifier is disclosed with a main amplifier having a main input in communication with a radio frequency (RF) signal input and a main output in communication with a RF signal output. Also included is a peaking amplifier having a peak input in communication with the RF signal input and a peak output in communication with the RF signal input. Further included is main neutralization circuitry having a main neutralization input in communication with the peak input and a main neutralization output in communication with the main input, wherein the main neutralization circuitry is configured to inject a main neutralization signal into the main input such that the main neutralization signal is 18010% out of phase and equal in amplitude to within 10% of a main parasitic feedback signal passed from the main output to the main input by way of a main parasitic feedback capacitance.

An active electronic device that enables bidirectional communication over a single antenna or path is disclosed. The device may be characterized by a forward path (from an input to an antenna port) offering high gain, and a reverse path (to a receiver port) that can be configured as an finite impulse response (FIR) filter. An amplifier of the device is disclosed, the amplifier allowing for tuning of output resistance using passive mixers.

An active electronic device that enables bidirectional communication over a single antenna or path is disclosed. The device may be characterized by a forward path (from an input to an antenna port) offering high gain, and a reverse path (to a receiver port) that can be configured as an finite impulse response (FIR) filter. An amplifier of the device is disclosed, the amplifier allowing for tuning of output resistance using passive mixers.

A power supply system comprises an amplifier stage that includes at least one transistor, for example an LDMOS transistor. The transistor is connected to a supply voltage via a power connection, and is controlled by a control voltage at the control connection of the transistor. In some implementations, a first controller is provided for adjusting the control voltage of the transistor, and a second controller is provided for adjusting the supply voltage. In some implementations, one of the controllers is designed to feed a state signal to the other controller, and the other controller is designed to evaluate the state signal.