A cascode amplifier circuit comprising a power amplifier block having a first transistor and a second transistor. The amplifier circuit also comprises: a bias generator block coupled to the first transistor and being configured to provide a reference voltage to the power amplifier block; and a current control block coupled to the second transistor of the power amplifier block, the current control block being configured to adjust a gate bias to the second transistor of the power amplifier block to maintain a constant quiescent current.

An apparatus is disclosed, comprising means for storing reference data indicative of characteristics for each of two or more amplifiers for amplifying signals in two or more respective bands, the reference data including voltage characteristics required by the particular amplifier to achieve a particular output power for a range of output power values for its respective frequency band. The apparatus may comprise means for receiving at least a first required output power for a first amplifier and a second required output power for a second amplifier, and determining, based on the reference data, the voltage characteristics required for the first amplifier to achieve the first required output power and the voltage characteristics required for the second amplifier to achieve the second required output power.

A system includes a reference field effect transistor (FET), wherein the reference FET is a depletion mode transistor, and a bias control circuit. The bias control circuit includes a voltage sensor connected to a drain terminal of the reference FET. The voltage sensor is configured to measure a voltage at the drain terminal of the reference FET as a measured voltage, determine a voltage difference between a reference voltage and the measured voltage, and output the voltage difference at a voltage sensor output terminal. The system includes a translation circuit connected the voltage sensor output terminal. The translation circuit is configured to convert the voltage difference into a negative gate bias voltage, and apply the negative gate bias voltage to a gate terminal of the reference FET.

The present disclosure in some embodiments relates to a method of calibrating a power amplifier performance and an apparatus therefor, which provide an optimal calibration of the output characteristics of a power amplifier to all possible combinations in the input signal source by enabling individualized calibrations for changes in the output characteristics at room temperature and changing temperatures, thereby improving the performance of the power amplifier.

A reconfigurable amplifier configured to decrease radio frequency (RF) signal distortion and increase dynamic range is disclosed. The reconfigurable amplifier includes an amplifier having an RF signal input, an RF signal output, and a bias signal input. A distortion detection network has a detector input coupled to the RF signal output and a detector output, wherein the distortion detector network is configured to generate a detection signal that is proportional to distortion at the RF signal output. A bias controller has a detection signal input coupled to the detector output and a bias output coupled to the bias signal input. The bias controller is configured to generate a bias signal that dynamically shifts level at the bias output to reduce the distortion at the RF signal output in response to the detection signal.

Disclosed are systems configured to deliver wireless charging power to electronic devices and methods for delivering wireless charging power. In some implementations, a system can include a programmable radio-frequency generator capable of generating a beam of electromagnetic pulsed radiation and plurality of solid-state amplifiers to amplify the beam of electromagnetic pulsed radiation. The amplified beam of electromagnetic pulsed radiation can be configured to wirelessly charge electronic devices at distances greater than about 100 meters.

A power supply circuitry includes a first circuitry, a second circuitry, a fourth circuitry, and a fifth circuitry. The first circuitry outputs a first current based on a drive signal. The second circuitry generates a second current according to the first current. The fourth circuitry generates the drive signal based on a first voltage according to the first current. The fifth circuitry outputs a second voltage based on the first current and on the second current.

Disclosed examples include differential amplifier circuits and variable neutralization circuits for providing an adjustable neutralization impedance between an amplifier input node and an amplifier output node, including neutralization impedance T circuits with first and second impedance elements in series between the amplifier input and output, and a third impedance element, including a first terminal connected to a node between the first and second impedance elements, and a second terminal connected to a transistor. The transistor operates according to a control signal to control the neutralization impedance between the amplifier input node and the amplifier output node.

Bias arrangements for amplifiers are disclosed. An example bias arrangement for an amplifier includes a bias circuit, configured to produce a bias signal for the amplifier; a linearization circuit, configured to improve linearity of the amplifier by modifying the bias signal produced by the bias circuit to produce a modified bias signal to be provided to the amplifier; and a coupling circuit, configured to couple the bias circuit and the linearization circuit. Providing separate bias and linearization circuits coupled to one another by a coupling circuit allows separating a linearization operation from a biasing loop to overcome some drawbacks of prior art bias arrangements that utilize a single biasing loop.

Provided are a gain compensation device and a bias circuit device. A compensation bias current is generated by the gain compensation device to compensate the gain deviation of power amplifier and improve stability of power amplifier. Through high-temperature compensation unit and low-temperature compensation unit in different gears, gain of power amplifier is compensated along with temperature changes, thereby improving feasibility of the gain compensation device. It takes small space, and the circuit only includes the circuits corresponding to high-temperature compensation unit and low-temperature compensation unit, so the circuit is relatively simple and beneficial to miniaturization. In the bias circuit device, based on an initial bias current provided by a bandgap reference, the gain compensation device is added to generate a compensation bias current, and the initial bias current and compensation bias current are superimposed, so that the gain of power amplifier is further compensated, which improves stability of power amplifier.