Circuits, devices and methods related to multi-mode power amplifiers. A power amplifier (PA) assembly can include a radio-frequency (RF) amplification path having a first stage and a second stage, with each stage including a transistor. The PA assembly can further include a biasing circuit having a first bias path between a supply node and the base of a corresponding transistor. The PA assembly can further include a linearizing circuit implemented as either or both of a second bias path and a coupling path relative to the first bias path. The second bias path can be configured to provide an additional base bias current to the base under a selected condition. The coupling path can be configured to improve linearity of the corresponding transistor operating in a first mode while allowing a ballast resistance to be sufficiently robust for the corresponding transistor operating in a second mode.

Power amplifier bias circuit. A power amplifier bias circuit can include an emitter follower device and an emitter follower mirror device coupled to form a mirror configuration. The emitter follower device can be configured to provide a bias signal for a power amplifier at an output port. The power amplifier bias circuit can include a reference device configured to mirror an amplifying device of the power amplifier. The emitter follower mirror device can be configured to provide a mirror bias signal to the reference device.

A Doherty power amplifier includes a carrier amplifier, a peaking amplifier, and a peaking amplifier bias circuit coupled to the peaking amplifier and configured to provide a peaking amplifier bias signal to the peaking amplifier based on a saturation level of the carrier amplifier.

Circuits and methods for adjusting one or more operation parameters of a semiconductor device. One example of a circuit includes a first semiconductor device, a beta sensing circuit coupled to the first semiconductor device and configured to measure a current gain of the first semiconductor device and generate a first control signal based on a value of the current gain of the first semiconductor device, and a reference control circuit coupled to the beta sensing circuit and configured to receive the first control signal and adjust an operation parameter of the first semiconductor device based on the value of the current gain of the first semiconductor device.

A Doherty power amplifier includes a carrier amplifier, a peaking amplifier, and a peaking amplifier bias circuit coupled to the peaking amplifier and configured to provide a peaking amplifier bias signal to the peaking amplifier based on a saturation level of the carrier amplifier.

Certain aspects of the present disclosure generally relate to an amplification circuit. The amplification circuit generally includes: a first amplification path comprising a first amplification transistor and coupled between an input node of the amplification circuit and an output node of the amplification circuit; and a second amplification path comprising a second amplification transistor and coupled between the input node and the output node, wherein the second amplification path further includes an attenuator coupled between the input node of the amplification circuit and a control input of the second amplification transistor.

Various methods and circuital arrangements for biasing one or more gates of stacked transistors of an amplifier are presented, where the amplifier can be an envelope tracking amplifier. Circuital arrangements to generate reference gate-to-source voltages for biasing of the gates of the transistors of the stack are also presented. Particular biasing for a case of an input transistor of the stack is also presented.

An RF amplifier module that has a plurality of amplifiers wherein at least one of the amplifiers is powered via an envelope tracking module. The biasing input of at least one of the amplifiers is provided to the first amplifier to power the first amplifier to reduce power consumption. The first amplifier may also be powered via fixed biasing to provide greater stability of the module.

A radio-frequency power amplifier device includes: a carrier amplifier semiconductor device and a peak amplifier semiconductor device on a multilayer submount substrate; a bias power supply semiconductor device; second radio-frequency signal wiring that transmits radio-frequency signal to the carrier amplifier semiconductor device and the peak amplifier semiconductor device; and carrier-amplifier bias power supply wiring that is wired in a third wiring layer and supplies a bias power supply voltage. The second radio-frequency signal wiring and the carrier-amplifier bias power supply wiring intersect in a plan view. The radio-frequency power amplifier device includes: a shield pattern that is located in a second wiring layer between a first wiring layer and the third wiring layer; and one or more connection vias disposed in an extension direction of the carrier-amplifier bias power supply wiring. The one or more connection vias are connected to the shield pattern.

Disclosed are a multimode power amplifier, also a method for implementing different work mode switching by the multimode power amplifier and a mobile terminal using the multimode power amplifier. The multimode power amplifier includes at least two stage amplification circuits, each stage amplification circuit is connected in serial way; each stage amplification circuit has at least one basic amplification unit array, the amplification unit array is composed of multiple basic amplification units in parallel way. Bias voltage of each basic amplification unit array is controlled independently. By configuring the bias voltage flexibly, the multimode power amplifier can implement the switching between saturation mode and linear mode, and meets the actual needs of multi-communication mode. In addition, the multimode power amplifier also has the advantages of lower cost, simple and flexible circuit, and easy realization.