Abstract: Apparatus and methods are described for biasing amplifiers with multiple outputs. A semiconductor die may include a reference Field Effect Transistor (FET) integrated on the semiconductor die and coupled to an amplifier integrated on the semiconductor die. A voltage offset circuit may also be integrated on the semiconductor die for determining the voltage needed to operate the amplifier.

Abstract: Apparatus and methods are described for biasing amplifiers with multiple outputs. A semiconductor die may include a reference Field Effect Transistor (FET) integrated on the semiconductor die and coupled to an amplifier integrated on the semiconductor die. A voltage offset circuit may also be integrated on the semiconductor die for determining the voltage needed to operate the amplifier.

Abstract: An adaptive bias control circuit for use with a radio frequency (RF) power amplifier, the RF power amplifier having an input (112) for receiving an input signal having a varying amplitude, an output (116), a first transistor (110), and a plurality of operating performance characteristics responsive to a quiescent operating point established by a bias current in the RF power amplifier, the bias control circuit having: a first circuit (120) coupled to the RF power amplifier for receiving a portion of the input signal; and a second transistor (122) for generating a rectified signal from the portion of the input signal, the rectified signal for causing the bias current to be controlled as a function of the amplitude of the input signal, the second transistor having a first and second terminal connected together and coupled to the first circuit and a third terminal coupled to a fixed voltage.

Abstract: An active bias compensation circuit for use with a radio frequency (“RF”) power amplifier, the RF amplifier having an input (112), an output (116), a first transistor (110), and a plurality of operating performance characteristics responsive to a quiescent operating point established by a bias current in the RF amplifier. The active bias compensation circuit includes: a second transistor (120) operatively coupled to the RF amplifier and having a first, second and third terminal and further configured to have essentially the same electrical and thermal characteristics as the first transistor; and a first circuit (130) coupled between the first and second terminal of the second transistor for causing a desired quiescent operating current to be set and maintained in said RF power amplifier, independent of factors such as temperature and process variation.

Abstract: An active bias compensation circuit for use with a radio frequency (“RF”) power amplifier, the RF amplifier having an input (112), an output (116), a first transistor (110), and a plurality of operating performance characteristics responsive to a quiescent operating point established by a bias current in the RF amplifier. The active bias compensation circuit includes: a second transistor (120) operatively coupled to the RF amplifier and having a first, second and third terminal and further configured to have essentially the same electrical and thermal characteristics as the first transistor; and a first circuit (130) coupled between the first and second terminal of the second transistor for causing a desired quiescent operating current to be set and maintained in said RF power amplifier, independent of factors such as temperature and process variation.

Abstract: An adaptive bias control circuit for use with a radio frequency (RF) power amplifier, the RF power amplifier having an input (112) for receiving an input signal having a varying amplitude, an output (116), a first transistor (110), and a plurality of operating performance characteristics responsive to a quiescent operating point established by a bias current in the RF power amplifier, the bias control circuit having: a first circuit (120) coupled to the RF power amplifier for receiving a portion of the input signal; and a second transistor (122) for generating a rectified signal from the portion of the input signal, the rectified signal for causing the bias current to be controlled as a function of the amplitude of the input signal, the second transistor having a first and second terminal connected together and coupled to the first circuit and a third terminal coupled to a fixed voltage.

Abstract: An adaptive bias control circuit for use with a radio frequency (RF) power amplifier, the RF power amplifier having an input (112) for receiving an input signal having a varying amplitude, an output (116), a first transistor (110), and a plurality of operating performance characteristics responsive to a quiescent operating point established by a bias current in the RF power amplifier, the bias control circuit having: a first circuit (120) coupled to the RF power amplifier for receiving a portion of the input signal; and a second transistor (122) for generating a rectified signal from the portion of the input signal, the rectified signal for causing the bias current to be controlled as a function of the amplitude of the input signal, the second transistor having a first and second terminal connected together and coupled to the first circuit and a third terminal coupled to a ground potential.

Abstract: A radio frequency (RF) power amplifier device that includes an RF amplification element coupled to an output matching circuit further includes a match extender that provides an extension of the output matching circuit beyond the RF power amplifier device. The match extender provides an apparatus by which the circuitry of the output matching circuit may be extended outside of the RF power amplifier device and by which output matching circuitry external to the RF power amplifier device may provide a matching impedance that originates at a die plane of the RF amplification element.

Abstract: A radio frequency (RF) power amplifier device that includes an RF amplification element coupled to an output matching circuit further includes a match extender that provides an extension of the output matching circuit beyond the RF power amplifier device. The match extender provides an apparatus by which the circuitry of the output matching circuit may be extended outside of the RF power amplifier device and by which output matching circuitry external to the RF power amplifier device may provide a matching impedance that originates at a die plane of the RF amplification element.