Abstract: An amplifier device, such as a Doherty amplifier device, may include an extra lead and decoupling capacitor coupled to radio frequency (RF) cold points of output impedance matching circuitry of multiple amplification paths, such as a carrier path and peaking path, of the amplifier device. The extra lead and the decoupling capacitor are configured to provide low frequency resonance decoupling for the multiple amplification paths. A drain bias voltage may be provided to the drain terminals of transistors of amplifiers of the amplifier device via the extra lead. An integrated passive device (IPD) including a wire fence and one or more conductive pads may be disposed between a carrier amplifier die and a peaking amplifier. The extra lead may be coupled to the RF cold points via the IPD. The wire fence may mitigate RF interference between the carrier amplifier die and the peaking amplifier die.

Abstract: Embodiments of a device and method are disclosed. In an embodiment, an RF amplifier includes first and second RF signal paths having RF input interfaces, RF output interfaces, and corresponding transistors connected between the respective RF input interfaces and RF output interfaces, wherein control terminals of the transistors are connected to the RF input interfaces and current conducting terminals of the transistors are connected to the corresponding RF output interfaces. The RF amplifier including a conductive path between the current conducting terminal of the first transistor and the current conducting terminal of the second transistor, wherein the conductive path includes a first inductance, a second inductance, and a capacitance electrically connected between the first inductance and the second inductance.

Abstract: The embodiments described herein can provide radio frequency (RF) amplifiers, and particularly Doherty power amplifiers. The Doherty amplifiers include a carrier amplifier, at least one peaking amplifier, and a combiner. In general, these Doherty amplifiers include an adaptive impedance transformation that provides a phase shift and modifies the impedance presented to one or more peaking amplifier(s) in the Doherty amplifier. Specifically, the combiner includes at least a first impedance transformer, second impedance transformer, and a third impedance transformer coupled between the first impedance transformer and the second impedance transformer. In accordance with the embodiments described herein, the third impedance transformer is configured to both provide both a phase shift and an impedance transformation.

Abstract: Embodiments of a device and method are disclosed. In an embodiment, an RF amplifier includes first and second RF signal paths having RF input interfaces, RF output interfaces, and corresponding transistors connected between the respective RF input interfaces and RF output interfaces, wherein control terminals of the transistors are connected to the RF input interfaces and current conducting terminals of the transistors are connected to the corresponding RF output interfaces. The RF amplifier including a conductive path between the current conducting terminal of the first transistor and the current conducting terminal of the second transistor, wherein the conductive path includes a first inductance, a second inductance, and a capacitance electrically connected between the first inductance and the second inductance.