Embodiments of the present disclosure describe apparatuses, methods, and systems of front end module (FEM) having a feedback path that includes a passive attenuation network. The passive attenuation network may provide a feedback signal to a receive output port of the FEM that may be used as a basis for predistortion. Other embodiments may also be described and/or claimed.

Embodiments of the present disclosure describe apparatuses, methods, and systems of front end module (FEM) having a feedback path that includes a passive attenuation network. The passive attenuation network may provide a feedback signal to a receive output port of the FEM that may be used as a basis for predistortion. Other embodiments may also be described and/or claimed.

An apparatus includes an input port, an output port, and a plurality of amplifier stages connected in parallel between the input port and the output port. Each of the amplifier stages comprises a common source field effect transistor (CSFET) and at least two common gate field effect transistors (CGFETs) coupled in series with a drain of the common source FET. At least one of the common gate field effect transistors of each stage includes a stabilizing network connected between drain and source diffusions.

A high-frequency signal amplifier circuit is used in a front-end circuit configured to propagate a high-frequency transmission signal and a high-frequency reception signal, and includes an amplifier transistor configured to amplify the high-frequency transmission signal; a bias circuit configured to supply a bias to a signal input end of the amplifier transistor; and a ferrite bead, one end of which is connected to a bias output end of the bias circuit and the other end of which is connected to the signal input end of the amplifier transistor, having characteristics in which impedance in a difference frequency band between the high-frequency transmission signal and the high-frequency reception signal is higher than impedance in DC.

A high-frequency signal amplifier circuit is used in a front-end circuit configured to propagate a high-frequency transmission signal and a high-frequency reception signal, and includes an amplifier transistor configured to amplify the high-frequency transmission signal; a bias circuit configured to supply a bias to a signal input end of the amplifier transistor; and a ferrite bead, one end of which is connected to a bias output end of the bias circuit and the other end of which is connected to the signal input end of the amplifier transistor, having characteristics in which impedance in a difference frequency band between the high-frequency transmission signal and the high-frequency reception signal is higher than impedance in DC.

A delay-compensating power management circuit is provided. The power management circuit includes a power management integrated circuit (PMIC) configured to generate a time-variant voltage(s) based on a time-variant target voltage(s) for amplifying an analog signal(s) associated with a time-variant power envelope(s). A voltage processing circuit is provided in the power management circuit to determine a temporal offset, which can be positive or negative, between the time-variant power envelope(s) and the time-variant target voltage(s). Accordingly, the voltage processing circuit modifies the time-variant target voltage(s) to substantially reduce the determined temporal offset and thereby realign the time-variant target voltage(s) with the time-variant power envelope(s). By realigning the time variant target voltage(s) with the time-variant power envelope(s), it is possible to align the time-variant voltage(s) with the time-variant power envelope(s) to reduce distortions (e.g., amplitude clipping) during amplification of the analog signal.

A delay-compensating power management circuit is provided. The power management circuit includes a power management integrated circuit (PMIC) configured to generate a time-variant voltage(s) based on a time-variant target voltage(s) for amplifying an analog signal(s) associated with a time-variant power envelope(s). A voltage processing circuit is provided in the power management circuit to determine a temporal offset, which can be positive or negative, between the time-variant power envelope(s) and the time-variant target voltage(s). Accordingly, the voltage processing circuit modifies the time-variant target voltage(s) to substantially reduce the determined temporal offset and thereby realign the time-variant target voltage(s) with the time-variant power envelope(s). By realigning the time variant target voltage(s) with the time-variant power envelope(s), it is possible to align the time-variant voltage(s) with the time-variant power envelope(s) to reduce distortions (e.g., amplitude clipping) during amplification of the analog signal.

Envelope tracking power supply circuitry includes a look up table (LUT) configured to provide a target supply voltage based on a power envelope measurement. The target supply voltage is dynamically adjusted based on a delay between the power envelope of an RF signal and a provided envelope tracking supply voltage. The envelope tracking supply voltage is generated from the adjusted target supply voltage in order to synchronize the envelope tracking supply voltage with the power envelope of the RF signal.

A delay-compensating power management integrated circuit (PMIC) is provided. The PMIC includes a target voltage circuit configured to generate a target voltage that is utilized for generating a time-variant voltage to amplify an analog signal. The target voltage is generated based on a time-variant envelope of the analog signal but lags behind the time-variant envelope by a temporal delay(s) due to an inherent processing delay in the target voltage circuit. In this regard, a voltage processing circuit is provided in the target voltage circuit to generate a modified target voltage that is time-adjusted relative to the target voltage to substantially offset the temporal delay(s). By generating the time-variant voltage based on the modified target voltage, the time-variant voltage can be better aligned with the time-variant envelope of the analog signal, thus helping to reduce amplitude distortion when amplifying the analog signal.

A delay-compensating power management integrated circuit (PMIC) is provided. The PMIC includes a target voltage circuit configured to generate a target voltage that is utilized for generating a time-variant voltage to amplify an analog signal. The target voltage is generated based on a time-variant envelope of the analog signal but lags behind the time-variant envelope by a temporal delay(s) due to an inherent processing delay in the target voltage circuit. In this regard, a voltage processing circuit is provided in the target voltage circuit to generate a modified target voltage that is time-adjusted relative to the target voltage to substantially offset the temporal delay(s). By generating the time-variant voltage based on the modified target voltage, the time-variant voltage can be better aligned with the time-variant envelope of the analog signal, thus helping to reduce amplitude distortion when amplifying the analog signal.