A variable gain amplifier includes a first transistor group which is connected to an input terminal and an output terminal, and which amplifies a signal from the input terminal to output the amplified signal to the output terminal; a second transistor group connected to the input terminal; a third transistor group connected to the output terminal; and a controller configured to control the first transistor group, the second transistor group, and the third transistor group so that a total number of the number of transistors to be turned on in the first transistor group and the second transistor group is kept at a constant value, and total numbers of transistors to be turned on in the first transistor group and in the third transistor group are the same.

Methods and apparatus for providing adaptive biasing to power amplifiers. Adaptive bias circuits are configured to provide sharp turn on and/or current clamping to improve the efficiency of a power amplifier over a wide input signal bandwidth. Sharp turn on may be achieved using a subtraction technique to subtract outputs from multiple detectors. Clamping may be achieved using MOSFET device characteristics to pull the device from the triode region into the saturation, subtraction techniques to subtract the outputs from multiple detectors, and/or by using circuit devices, such as diodes.

A power amplifier circuitry (100) comprises: a transistor stack (110) comprising at least two stacked transistor units (112A, 112B, 112C) for amplifying input signals; wherein each stacked transistor unit (112A, 112B, 112C) comprises a plurality of controllable segments (120-1 to 120-N, 130-1 to 130-N, 140-1 to 140-N), each comprising a segment transistor (122, 132, 142), wherein source terminals (123, 133, 143) within each transistor unit are connected, drain terminals (125, 135, 145) within each transistor unit are connected and gate terminals (124, 134, 144) within each transistor unit are connected, wherein each segment transistor (122, 132, 142) further comprises a back gate terminal (126, 136, 146) for setting a body bias, wherein at least two of the segment transistors (122, 132, 142) within each transistor unit have independently connected back gate terminals (126, 136, 146); and a control unit (190) configured to control the body bias for selecting an amplifier class of each of the controllable segments (120-1 to 120-N, 130-1 to 130-N, 140-1 to 140-N) of each of the stacked transistor units (112A, 112B, 112C).

Circuits and methods for achieving good AM-AM and AM-PM metrics while achieving good power, PAE, linearity, and EVM performance in an amplifier. Embodiments provide an equalization approach which compensates for AM-AM and AM-PM variations in an amplifier by controlling bias voltage versus output power to alter the AM-AM and AM-PM profiles imposed by the amplifier. Differential amplifier embodiments include cross-coupled common-gate transistors that generate an equalization voltage that alters the gate bias voltage of respective main FETs in proportion to a power level present at the respective drains of the main FETs. Single-ended amplifier embodiments include an equalization circuit that alters the bias voltage to the gate of a main FET in proportion to a power level present at the main FET drain. Embodiments may also include a linearization circuit which alters the AM-PM profile of an input signal to compensate for the AM-PM profile imposed by a coupled amplifier.

Circuits and methods for achieving good AM-AM and AM-PM metrics while achieving good power, PAE, linearity, and EVM performance in an amplifier. Embodiments provide an equalization approach which compensates for AM-AM and AM-PM variations in an amplifier by controlling bias voltage versus output power to alter the AM-AM and AM-PM profiles imposed by the amplifier. Differential amplifier embodiments include cross-coupled common-gate transistors that generate an equalization voltage that alters the gate bias voltage of respective main FETs in proportion to a power level present at the respective drains of the main FETs. Single-ended amplifier embodiments include an equalization circuit that alters the bias voltage to the gate of a main FET in proportion to a power level present at the main FET drain. Embodiments may also include a linearization circuit which alters the AM-PM profile of an input signal to compensate for the AM-PM profile imposed by a coupled amplifier.

A power amplifier circuitry (100) comprises: a transistor stack (110) comprising at least two stacked transistor units (112A, 112B, 112C) for amplifying input signals; wherein each stacked transistor unit (112A, 112B, 112C) comprises a plurality of controllable segments (120-1 to 120-N, 130-1 to 130-N, 140-1 to 140-N), each comprising a segment transistor (122, 132, 142), wherein source terminals (123, 133, 143) within each transistor unit are connected, drain terminals (125, 135, 145) within each transistor unit are connected and gate terminals (124, 134, 144) within each transistor unit are connected, wherein each segment transistor (122, 132, 142) further comprises a back gate terminal (126, 136, 146) for setting a body bias, wherein at least two of the segment transistors (122, 132, 142) within each transistor unit have independently connected back gate terminals (126, 136, 146); and a control unit (190) configured to control the body bias for selecting an amplifier class of each of the controllable segments (120-1 to 120-N, 130-1 to 130-N, 140-1 to 140-N) of each of the stacked transistor units (112A, 112B, 112C).

A variable gain amplifier includes a first transistor group which is connected to an input terminal and an output terminal, and which amplifies a signal from the input terminal to output the amplified signal to the output terminal; a second transistor group connected to the input terminal; a third transistor group connected to the output terminal; and a controller configured to control the first transistor group, the second transistor group, and the third transistor group so that a total number of the number of transistors to be turned on in the first transistor group and the second transistor group is kept at a constant value, and total numbers of transistors to be turned on in the first transistor group and in the third transistor group are the same.

Techniques and apparatus for reducing sensitivity (e.g., less gain variation due to parasitic capacitance) in dynamic amplifiers. One example dynamic amplifier generally includes a pair of differential input transistors, a pair of cross-coupled switches coupled between the pair of differential input transistors and a pair of differential output nodes for the dynamic amplifier, a first pair of switches coupled between the pair of differential input transistors and the pair of differential output nodes, and a second pair of switches coupled between the pair of differential input transistors and the pair of differential output nodes.

Methods and apparatus for providing adaptive biasing to power amplifiers. Adaptive bias circuits are configured to provide sharp turn on and/or current clamping to improve the efficiency of a power amplifier over a wide input signal bandwidth. Sharp turn on may be achieved using a subtraction technique to subtract outputs from multiple detectors. Clamping may be achieved using MOSFET device characteristics to pull the device from the triode region into the saturation, subtraction techniques to subtract the outputs from multiple detectors, and/or by using circuit devices, such as diodes.

The present disclosure generally relates to semiconductor structures and, more particularly, to a fully depleted silicon on insulator power amplifier with unique biases and voltage standing wave ratio protection and methods of manufacture. The structure includes a pseudo-differential common source amplifier; first stage cascode devices connected to the pseudo-differential common source amplifier and protecting the pseudo-differential common source amplifier from an over stress; second stage cascode devices connected to the first stage cascode devices and providing differential outputs; and at least one loop receiving the differential outputs from the second stage cascode devices and feeding back the differential outputs to the second stage cascode devices.