Methods and systems for modulating an amplifier power supply to efficiently attain amplified RF output power with much lower power dissipation than existing amplifiers.

An envelope tracking (ET) amplifier apparatus is provided. The ET amplifier apparatus includes a distributed ET integrated circuit (DETIC) configured to generate a distributed ET voltage. The DETIC may be coupled to a higher-bandwidth (HB) amplifier circuit and a lower-bandwidth (LB) amplifier circuit configured to amplify an HB radio frequency (RF) signal and an LB RF signal, respectively. In examples discussed herein, the DETIC may be configured to selectively provide the ET voltage to one of the HB amplifier circuit and the LB amplifier circuit, depending on which of the HB amplifier circuit and the LB amplifier circuit is activated. By providing the DETIC in proximity to the HB amplifier circuit and the LB amplifier circuit, it may be possible to reduce potential distortion to the HB RF signal and the LB RF signal, without significantly increasing footprint of the ET amplifier apparatus.

An envelope tracking integrated circuit having a tracker circuitry configured to generate a modulated supply voltage for a radio frequency power amplifier in response to an envelope of a radio frequency signal to be amplified by the radio frequency power amplifier is disclosed. Also included is a charge pump system configured to generate a tracker supply voltage for the tracker circuitry. Further included is an analog multiplexer configured to receive the tracker supply voltage and a battery source voltage and output a selected one of the tracker supply voltage and the battery source voltage in response to a voltage select signal. A digital processor further included in the envelope tracking integrated circuit is configured to control portions of the tracker circuitry and be powered by the selected one of the tracker supply voltage and the battery source voltage during transmission gaps when the radio frequency signal is not transmitted.

Amplification device and processes capable of miniaturization in a device for performing linear amplification and switching amplification operations on incoming signals are provided. The amplifying device includes a first amplifying unit for amplifying an input signal and outputting a first output signal, the input switch unit connected in parallel with the first amplifying unit for performing a switching operation by an input signal and outputting a switch output signal, and a second amplifying unit for amplifying a first output signal or a switch output signal and outputting a second output signal, and the first amplifying unit or the input switch unit operates based on the type of the input signal.

A digital isolator comprising a set of bipolar transistors and an inductor capacitor (LC) oscillator coupled to the set of bipolar transistors in series, wherein the LC oscillator is configured to be turned on and off based on the current applied to the set of bipolar transistors or the LC oscillator and generate a set of differential signals based on the current flowing through the set of bipolar transistors and mimicking the operational characteristics of an optocoupler.

The present disclosure relates to an envelope tracking (ET) amplification architecture, which includes a power amplifier (PA) block configured to amplify a radio frequency (RF) input signal and provide an RF output signal, and an ET voltage block configured to provide modulated voltages to the PA block as power supplies. Herein, the modulated voltages are provided based on a configuration of the PA block and from one pulsed ramp signal, which contains envelope information of the RF input signal. The modulated voltages are eligible to have at least one of a time delay difference, an amplitude difference, and a phase difference.

An envelope tracking (ET) amplifier apparatus is provided. The ET amplifier apparatus includes an ET integrated circuit (ETIC) having a number of voltage circuits coupled to a common port and configured to generate an ET voltage(s) based on a number of ET target voltages, respectively. In examples discussed herein, a selected voltage circuit(s) in the ETIC receives a maximum ET target voltage among all the ET target voltages and is configured to generate a reference ET voltage based on the maximum ET target voltage. As such, another voltage circuit(s), which happens to receive the maximum ET target voltage, may simply treat the reference ET voltage as a respective ET voltage(s) instead of generating the respective ET voltage(s). As a result, it may be possible to opportunistically turn off or reduce functionality of the voltage circuit(s) to help reduce peak battery current and improve heat dissipation in the ET amplifier apparatus.

The present disclosure relates to a power management circuit (PMC) with a dual charge pump (DCP) structure. The DCP structure includes a first switch network having a first capacitor, a second switch network having a second capacitor, and a connection switch coupled between the first switch network and the second switch network. Herein, the first capacitor and the second capacitor are electrically coupled in series between a battery terminal and a ground terminal or electrically coupled in parallel between the battery terminal and the ground terminal during a charging phase. The first capacitor and the second capacitor are electrically coupled in series between the battery terminal and a pump output terminal, or electrically coupled in parallel between the battery terminal and the pump output terminal, or electrically coupled in parallel between the ground terminal and the pump output terminal during a discharging phase.

An envelope tracking (ET) amplifier apparatus is provided. The ET amplifier apparatus includes an ET integrated circuit (IC) (ETIC) and a distributed ETIC (DETIC) coupled to the ETIC. The DETIC may be configured to provide a distributed voltage to a distributed amplifier circuit for amplifying a distributed radio frequency (RF) signal. In examples discussed herein, the ETIC is configured to generate a low-frequency current, which can affect the distributed voltage, at a desired level based on a feedback signal received from the DETIC. The DETIC may be configured to generate the feedback signal based on an indication(s) related to the distributed voltage. By dynamically adjusting the low-frequency current, and thus the distributed voltage, based on the feedback signal, it may be possible to maintain operating efficiency of the distributed amplifier circuit across a wider range of modulation bandwidth with minimal cost and/or size impact on the ET amplifier apparatus.

Systems, methods, and circuitries are provided for generating supply voltages for a power amplifier in a digital envelope tracking system. In one example, a voltage generation circuitry converts a source voltage into a supply voltage based on a target voltage. The voltage regulation circuitry includes an adjustable boost circuitry that multiplies the source voltage to generate an input voltage having a voltage equal to or greater than the source voltage and a step-down regulator circuitry that regulates the input voltage to generate a regulated output voltage having a voltage that is less than or equal to the input voltage. A voltage splitter circuitry is coupled to the regulated output voltage and is configured to generate at least one derived output voltage from the regulated output voltage. A supply modulator provides a selected one of the at least one derived output voltage to a power amplifier.