An amplification stage and a wideband power amplifier are provided. The amplification stage includes a stage input terminal, a stage output terminal, an amplifier, an input compensation network, and in output compensation network. At the stage input terminal is received a signal which is provided via the input compensation network to the amplifier. The input compensation network filters the signal to allow a wideband operation of the amplification stage around an operational frequency. The amplified signal provided by the amplifier is provided via the output compensation network to the stage output terminal. The output compensation network configured to allow a wideband operation of the amplification stage around the operational frequency with a minimal phase shift and distortion of amplitude and phase frequency response. The wideband power amplifier includes a plurality of amplification stage combined with transmission lines or their lumped element equivalents in a specific circuit topology.

A radio frequency (RF) power combining amplifier circuit has a circuit input and a circuit output. A first amplifier is connected to the circuit input and to a first bias input. A first output matching network is connected to an output of the first amplifier and to the circuit output. A second amplifier is connected to the circuit input and to a second bias input. A second output matching network is connected to an output of the second amplifier, and to the circuit output. A voltage level of an input signal applied to the circuit input, together with the respective first bias input and the second bias input, selectively activates the first amplifier and the second amplifier.

A radio frequency (RF) power combining amplifier circuit has a circuit input and a circuit output. A first amplifier is connected to the circuit input and to a first bias input. A first output matching network is connected to an output of the first amplifier and to the circuit output. A second amplifier is connected to the circuit input and to a second bias input. A second output matching network is connected to an output of the second amplifier, and to the circuit output. A voltage level of an input signal applied to the circuit input, together with the respective first bias input and the second bias input, selectively activates the first amplifier and the second amplifier.

An ESD protection circuit is connected in parallel to a MIM capacitor between a first terminal and a second terminal. First Schottky diodes are connected in series to each other and have anodes connected on the first terminal side and cathodes connected on the second terminal side. Second Schottky diodes are connected in series to each other and connected in anti-parallel to the first Schottky diodes. When an RF signal is inputted to neither the first terminal nor the second terminal, the first terminal has a higher DC voltage than that of the second terminal. The number of the first Schottky diodes is greater than the number of the second Schottky diodes. The number of the second Schottky diodes is set such that an amplitude of the RF signal does not attenuate to predetermined amplitude of the RF signal when the RF signal passes through the MIM capacitor.

An ESD protection circuit is connected in parallel to a MIM capacitor between a first terminal and a second terminal. First Schottky diodes are connected in series to each other and have anodes connected on the first terminal side and cathodes connected on the second terminal side. Second Schottky diodes are connected in series to each other and connected in anti-parallel to the first Schottky diodes. When an RF signal is inputted to neither the first terminal nor the second terminal, the first terminal has a higher DC voltage than that of the second terminal. The number of the first Schottky diodes is greater than the number of the second Schottky diodes. The number of the second Schottky diodes is set such that an amplitude of the RF signal does not attenuate to predetermined amplitude of the RF signal when the RF signal passes through the MIM capacitor.

A negative impedance circuit including: a first and a second bipolar transistors having a common collector, a base of the first transistor being connected to an emitter of the second transistor; a third and a fourth bipolar transistors having a common collector, a base of the third transistor being connected with an emitter of the fourth transistor, and at least one first impedance formed of one or of a plurality of passive components coupling the common collector of the first and second transistors to the common collector of the third and fourth transistors, a base of the second transistor being coupled to the collector of the third and fourth transistors and a base of the fourth transistor being coupled to the collector of the first and second transistors.

The embodiments described herein provide class F amplifiers and methods of operation. So implemented, the class F amplifiers can be used to provide high efficiency amplification for a variety of applications, including radio frequency (RF) applications. In general, the class F amplifiers are implemented with at least one transistor and an output matching network, where the output matching network includes a plurality of resonant circuits configured to facilitate class F amplifier operation. In addition to facilitating class F amplifier operation, the plurality of resonant circuits can also be implemented with other circuit elements to provide output impedance transformation in a way that facilitates efficient amplifier operation.

The embodiments described herein provide class F amplifiers and methods of operation. So implemented, the class F amplifiers can be used to provide high efficiency amplification for a variety of applications, including radio frequency (RF) applications. In general, the class F amplifiers are implemented with at least one transistor and an output matching network, where the output matching network includes a plurality of resonant circuits configured to facilitate class F amplifier operation. In addition to facilitating class F amplifier operation, the plurality of resonant circuits can also be implemented with other circuit elements to provide output impedance transformation in a way that facilitates efficient amplifier operation.

An integrated circuit (IC) includes a first switch, a second switch, and an amplifier electrically connected between the first switch and the second switch. An RF signal path passes through first switch, the amplifier, and the second switch in this order. The IC includes an input terminal and an output terminal that are to be connected to each other between the first switch and the amplifier or between the amplifier and the second switch outside of the IC with a component connected therebetween. In a top view of the IC, a first region of the first switch, a second region of the amplifier, and a third region of the second switch are disposed on a straight line such that a virtual straight line connects any point of the first region, any point of the second region, and any point of the second region in this order.

Methods related to power amplification systems with adjustable common base bias. A method of implementing a power amplification system can include providing a cascode amplifier coupled to a radio-frequency input signal and coupled to a radio-frequency output. The method can further include providing a biasing component configured to apply one or more biasing signals to the cascode amplifier, the biasing component including a bias controller and one or more bias components. Each respective bias component may be coupled to a respective bias transistor.