CN213521813U - System for adjusting power amplifier supply voltage based on transmitter branch gain setting - Google Patents

Abstract

The utility model discloses a system for adjusting power amplifier supply voltage based on transmitter branch gain setting, this system includes radio frequency transceiver, step-up/step-down DC-DC converter, radio frequency predistorter and power amplifier, and the radio frequency transceiver sends analog voltage signal to step-up/step-down DC-DC converter, controls step-up/step-down DC-DC converter to output corresponding power supply voltage value to power amplifier; the radio frequency transceiver sends a radio frequency excitation signal to the radio frequency predistorter, the radio frequency predistorter sends the processed radio frequency predistortion signal to the input end of the power amplifier, the power amplifier amplifies the received radio frequency predistortion signal, one part of the generated radio frequency amplified signal is sent to the antenna through the duplexer for transmission, and the other small part of the generated radio frequency amplified signal is fed back to the radio frequency predistorter through the coupler and is also fed back to the input end of a receiver of the radio frequency transceiver.

Description

System for adjusting power amplifier supply voltage based on transmitter branch gain setting

Technical Field

The utility model belongs to the radio communication field, concretely relates to system and method based on transmitter branch road gain setting adjusts power amplifier supply voltage.

Background

Generally, a power amplifier is used as a unit at the end of a wireless transmitter system or equipment, and when the power amplifier amplifies a radio frequency signal, the power supply voltage of the amplifier is constant no matter the average power of the amplified output radio frequency signal is stronger or weaker. When the power of the rf signal amplified by the power amplifier is weak, the power supply voltage of the amplifier remains constant, so that the dc power consumption of the power amplifier is also large, and the power efficiency is reduced. One effective way to improve power efficiency is to dynamically adjust the power supply voltage of the amplifier according to the strength of the output signal power of the power amplifier, where the power supply voltage increases with the increase of the output signal power of the amplifier, and decreases with the increase of the output signal power of the amplifier. The power efficiency can be effectively improved by adjusting the voltage value of the power supply, and particularly, the power efficiency is obviously improved when the power of an output signal is weak or weak.

The power modulator or the step-up-down DC-DC converter may provide a variable power supply voltage to the power amplifier, respectively, where the variable power supply voltage is varied according to an envelope of an input rf signal of the power amplifier or based on an average power of an output rf signal of the power amplifier in a next time period, and thus the corresponding manner of providing the variable power supply voltage to the power amplifier is referred to as an Envelope Tracking (ET) technique and an Average Power Tracking (APT) technique (as shown in fig. 1), respectively.

The envelope tracking technology is to extract an envelope of a radio frequency signal before the radio frequency signal enters a power amplifier, and then use the envelope signal as an input to control a power supply modulator (for example, an envelope tracking component in fig. 1) so that an output signal of the power supply modulator tracks the envelope change of the radio frequency signal, and is used as a power supply voltage of the power amplifier. The power supply voltage is a dynamic power supply voltage, and the dynamic power supply voltage tracks the envelope change of the radio frequency signal, so that the power supply current also rises or falls along with the envelope change of the radio frequency signal, and as a result, the redundant direct current voltage is reduced and the instantaneous power can be output by the amplifier, thereby improving the power efficiency to the maximum extent and prolonging the service duration of a power supply battery. However, the technical disadvantage is that the envelope variation of the rf signal output by the power modulator can cause severe nonlinear distortion of the power amplifier due to the limitation of the transmission bandwidth of the power modulator, thereby causing the performance of the transmitted signal to be degraded.

In contrast to Envelope Tracking (ET) techniques, Average Power Tracking (APT) techniques set the supply voltage through a boost/buck direct current-to-direct current (DC-DC) converter (such as the average power tracking component of fig. 1) based on an average power measurement or estimate of the rf signal over a next period of time. Compared with the Envelope Tracking (ET) technology, although the transmission power efficiency of the power amplifier is slightly low, the amplified radio-frequency signal has good performance of inhibiting in-band spectrum side lobes and out-of-band spurious, and the hardware is simpler to realize and has low cost. Compared with a conventional fixed power supply voltage power amplifier, the Average Power Tracking (APT) has high transmission power efficiency of the power amplifier and is not complex in hardware implementation. Especially, when a transmission signal with a larger peak power ratio to average power value (PAPR) is used and the power of an input radio frequency signal of the amplifier is lower, the Average Power Tracking (APT) can further improve the transmission power efficiency of the power amplifier compared with a conventional fixed power supply voltage power amplifier. However, this technique has the disadvantage of requiring the measurement or estimation of the average power of the rf signal over the next period of time, but has the difficulty of measuring or estimating the signal power over that period in real time and adjusting the supply voltage of the power amplifier in accordance with the measured or estimated signal power without delaying and affecting the transmission of the rf signal.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to the technical problem that above-mentioned exists, a in wireless transceiver and communication equipment, to next frame transmission radio frequency signal, directly adjust power amplifier multilevel power supply voltage according to transmitter branch road gain setting, provide corresponding power supply voltage value with the unnecessary direct current consumption of reduction to power amplifier to improve power amplifier power efficiency, and adopt Radio Frequency Predistorter (RFPD) to assist the nonlinear distortion that arouses under the excitation of different mains voltage to power amplifier to compensate simultaneously.

The gain of the transmitter branch is used to control the magnitude or strength of the average power of the output rf signal of the power amplifier in the next frame, and the relationship between the gain and the average power of the output rf signal is determined by the test calibration in the off-line mode.

The utility model adopts the technical proposal that:

a system for adjusting a power amplifier supply voltage based on a transmitter branch gain setting, the system comprising

The radio frequency transceiver comprises a radio frequency transmitter and a radio frequency receiver, wherein the radio frequency transmitter is used for outputting an analog voltage signal to control the output variable multilevel power supply voltage value of the step-up/step-down DC-DC converter to serve as the power supply voltage of the power amplifier, and outputting a radio frequency excitation signal to the radio frequency predistorter for predistortion processing;

the boost/buck direct current-direct current converter is used for receiving an analog voltage signal and an analog voltage signal output by the radio frequency transmitter, converting the input direct current voltage of the boost/buck direct current-direct current converter into a corresponding value in multi-level power supply voltage to serve as output voltage and supplying the power supply voltage value to the power amplifier, and the output voltage of the boost/buck direct current-direct current converter can be smaller than or larger than the input voltage;

the radio frequency predistorter is used for receiving a radio frequency excitation signal output by the radio frequency transmitter, carrying out predistortion processing on the radio frequency excitation signal to obtain a radio frequency predistortion signal, and outputting the radio frequency predistortion signal to the power amplifier; the power amplifier is also used for receiving a branch feedback radio frequency signal which is output by the power amplifier and coupled by the first coupler, and receiving a branch feedforward radio frequency signal which is output by the radio frequency transmitter and coupled by the radio frequency excitation signal and the second coupler;

the power amplifier is used for receiving the multi-level power supply voltage and the radio frequency predistortion signal, amplifying the radio frequency predistortion signal under the supply of a certain corresponding power supply voltage, sending the amplified radio frequency predistortion signal to the antenna as a radio frequency amplification signal, and feeding back a small part of a branch signal of the radio frequency amplification signal to the radio frequency predistorter after being coupled by the first coupler; and the analog voltage signal is also used for indicating the power strength of the radio frequency signal and feeding back the analog voltage signal to the radio frequency transceiver.

Preferably, the radio frequency predistorter comprises

The error signal generator is used for receiving a branch feedforward radio-frequency signal which is output by the radio-frequency transmitter and coupled by the second coupler and a branch feedback radio-frequency signal which is output by the power amplifier and coupled by the first coupler, respectively obtaining an equivalent baseband signal of the feedforward radio-frequency signal and an equivalent baseband signal of the feedback radio-frequency signal through down-conversion and demodulation processing, generating an error signal according to the difference of the equivalent baseband signal of the input feedforward radio-frequency signal and the equivalent baseband signal of the feedback radio-frequency signal in a time domain or a frequency domain, and sending the error signal to the predistortion coefficient generator;

the predistortion coefficient generator adaptively updates the predistortion coefficient according to the error signal until the error signal is reduced and converged, and sends the predistortion coefficient to the predistortion polynomial generator;

the predistortion polynomial generator is used for processing the baseband signal after the down-conversion, demodulation and low-pass filtering of the input radio frequency signal according to the updated predistortion coefficient to obtain a nonlinear polynomial and sending the nonlinear polynomial to the predistortion generator;

and the predistortion generator is used for processing the radio frequency excitation signal according to the nonlinear polynomial to obtain a radio frequency predistortion signal and sending the radio frequency predistortion signal to the power amplifier for power amplification.

Preferably, the radio frequency transmitter comprises

The analog-to-digital converter is used for receiving and converting the radio frequency signal power strength indication analog signal amplified by the power amplifier and sending the converted digital signal to the gain index control unit;

the gain index control unit is used for calibrating the actually-measured transmitting power and the target power through an off-line mode before the system leaves a factory so that the error between the actually-measured transmitting power and the target power is smaller than a threshold value, and setting a corresponding gain index as an output to respectively control the transmitting branch gain searching unit and the control index simplifying unit;

the transmitting branch circuit unit is used for receiving the gain index output by the gain index control unit, distributing the power amplification times or gains of all circuits in the transmitting branch circuit unit in a table look-up mode, and outputting a signal to set the corresponding power gain value of each circuit controlled by the transmitting branch circuit unit;

the transmitting branch circuit unit is used for setting corresponding power gain values of all circuits according to the power amplification times or gains of all circuits of the transmitting branch distributed by the transmitting branch gain searching unit, so that the power of the radio frequency excitation signal at the input end of the radio frequency predistorter is determined;

the control index simplifying unit is used for receiving the gain index output by the gain index control unit, carrying out simplification processing on the gain index to obtain a simplified control index, and sending the simplified control index to the power supply voltage searching unit;

and the power supply voltage searching unit is used for searching out a corresponding power supply voltage value according to the received simplified gain index, and converting the power supply voltage value into an analog voltage signal through the first digital-to-analog converter to control the step-up/step-down DC-DC converter to output a corresponding voltage level as the power supply voltage value of the power amplifier.

Preferably, the transmitting branch circuit unit comprises a second digital-to-analog converter, an analog filter, an amplifier, a modulator, an up-converter and a radio frequency power amplification driver;

the second digital-to-analog converter converts the digital baseband signal into an analog baseband signal, and the analog filter is positioned at the output end of the second digital-to-analog converter and is used for removing high-frequency components; the amplifier properly amplifies the filtered baseband signal, and the amplification gain of the amplifier is used as a part of the gain of the transmitting branch circuit; the modulator modulates the carrier signal by using the amplified input baseband signal, the modulated modulation signal realizes spectrum shifting, namely, a low-frequency spectrum is shifted to a high-frequency spectrum, and the up-converter and the modulator are designed together to realize spectrum shifting; the radio frequency power amplification driver is used for carrying out power amplification on the modulated modulation signal so as to meet the requirement of a following power amplifier on the power of an input signal of the power amplifier, the amplification gain of the power amplifier is fixed, the amplification gain of the radio frequency power amplification driver is adjustable, and the output signal power of the power amplifier can be increased or reduced by adjusting;

the sum of the power gains decibel of the analog filter, the amplifier, the modulator, the up-converter and the radio frequency power amplification driver forms the gain decibel of the transmitting branch, and the sum of the gain decibel of the transmitting branch and the gain of the power amplifier jointly determines the output power of the power amplifier.

Preferably, in the off-line mode, the system further comprises a radio frequency signal generator, a step-up/step-down dc-dc controller, an attenuator, a spectrum analyzer, and a computer, wherein an output terminal of the radio frequency signal generator is connected to the power amplifier, the attenuator, the spectrum analyzer, and the computer in sequence, and is used for collecting the output signal of the power amplifier, an output terminal of the radio frequency signal generator is also directly connected to the spectrum analyzer, and is used for collecting the input signal of the power amplifier, the step-up/step-down dc-dc controller outputs an analog voltage signal to control the output voltage of the step-up/step-down dc-dc converter, the voltage is the power supply voltage of the power amplifier

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a system that adjusts power amplifier multi-level power supply voltage based on transmitter branch road gain setting is distinguished and admirable because the average power of power amplifier output signal in next frame signal transmission time need not to measure is directly adjusted power amplifier power supply voltage based on transmitter branch road gain setting range, this is because the gain value of transmission branch road sets up the correlation with power amplifier output average power and is obtained through the actual measurement at the calibration stage, and store in the memory of transmitter, consequently, according to transmission branch road gain setting range and through the direct automatically regulated setting amplifier power supply voltage of look-up table method and need not the actual measurement, this transmission branch road gain setting is used for adjusting next frame radio frequency transmission signal power size. When the average power of the output signal required by the power amplifier is smaller in the next frame signal transmission time, the transmitting branch gain adjusts the power supply voltage of the power amplifier to correspondingly reduce the power supply voltage, so that the direct current is also reduced, and as a result, redundant direct current power consumption is reduced, the duration of a power supply battery is prolonged, and the energy or power efficiency of the power amplifier is improved. The power efficiency of the power amplifier can be further improved by adjusting the power supply voltage to reduce redundant direct current power consumption and simultaneously adopting the radio frequency predistorter to assist the excitation of the power supply voltage of the power amplifier so as to compensate the nonlinear distortion generated by the output signal of the power amplifier when the power of the output signal of the power amplifier is kept higher.

The utility model discloses a main application field is power amplifier in 4 th generation (4G) and 5 th generation (5G) wireless communication network transmission Base Station (BS) to and power amplifier in wireless local area network (Wi-Fi) Access Point (AP). In these applications, the power consumption of the power amplifier accounts for about 60% -70% of the total system power consumption, so improving the power efficiency of the power amplifier plays a significant role in improving the power efficiency of the total system.

The utility model discloses a social economy and environment beneficial effect adjust the many level supply voltage of power amplifier based on transmitter branch road gain setting to thereby reduce unnecessary power direct current consumption and improve power amplifier power transmission efficiency, save electric power operation cost, reduce carbon dioxide emission in the atmosphere, improve green environment. This is because the excess dc power consumption will be converted into heat energy to be dissipated into the atmosphere, which will increase the carbon dioxide emission in the atmosphere, generate greenhouse effect, and affect the environmental quality. Therefore, a technique for improving power transmission efficiency by reducing direct current power consumption for the system device is also called a time-of-life radio technique. Under the driving of two important factors, namely economic consideration and environmental consideration, improving the power efficiency of the power amplifier is the most promising development potential in many researches and is one of the most active innovative directions of the utility model.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic diagram of an envelope and average power pump (tracking) power amplifier system and Digital Predistortion (DPD) compensation configuration of the prior art;

FIG. 2 is a schematic diagram of a Radio Frequency Predistortion (RFPD) compensation in the prior art;

fig. 3 is a schematic diagram of a multi-level supply voltage and Radio Frequency Predistortion (RFPD) compensation 100 for a transmit branch gain adjusted power amplifier according to a first embodiment of the present invention;

fig. 4 is a detailed structural diagram of a transmit branch gain adjustment power amplifier supply voltage and Radio Frequency Predistortion (RFPD) compensation 600 according to a second embodiment of the present invention;

fig. 5 is a schematic diagram illustrating another detailed structure of the first embodiment of the present invention for adjusting the power supply voltage of the power amplifier by the transmission branch gain and compensating the Radio Frequency Predistortion (RFPD);

FIG. 6 is a circuit schematic of a predistortion generator;

fig. 7 is a waveform diagram illustrating indirect estimation of average power during the next frame of transmitted signal (within a certain time period) and direct adjustment of power amplifier supply voltage according to the setting of the transmission branch gain according to the present invention;

fig. 8 is a schematic structural diagram of the present invention for obtaining a Radio Frequency Predistortion (RFPD) coefficient 500 for a power amplifier under different supply voltages in an off-line mode, i.e. a non-operating mode;

fig. 9 is a flowchart illustrating the operation of the power amplifier under different supply voltages to obtain the Radio Frequency Predistortion (RFPD) coefficient as the initial value in the offline mode according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Example 1

The utility model discloses a system for adjusting power amplifier supply voltage based on transmitter branch gain setting, as shown in fig. 3, this system 100 includes power amplifier 116, radio frequency transceiver 170, radio frequency predistorter 150, step-up/step-down DC-DC converter 112.

Specifically (detailed functional block diagram please refer to fig. 5), the rf transceiver 170 includes an rf transmitter 180 and an rf receiver 190, wherein the rf transmitter 180 is configured to output a control analog voltage signal 108 to control a fixed power voltage of the output multi-level power voltage of the step-up/step-down dc-dc converter 112 as the power voltage of the power amplifier 116, and output an rf excitation signal 160 to the rf predistorter 150 for predistortion processing.

The step-up/down dc-dc converter 112 directly outputs the signal setting based on the range of the amplification gain region of the transmitting branch, and controls the step-up/down converter 112 to output a fixed power voltage of the corresponding multi-level power voltage value as the power voltage of the power amplifier 116, and the rf transceiver 170 can program the output signal of the range of the amplification gain region. The output power voltage value is controlled by the range of the gain region of the transmitting branch circuit, the gain region has a close corresponding relation with the region range in which the average power value of the next frame of radio frequency signals falls, when the average power value of the next frame of radio frequency signals is larger, the power voltage is relatively larger, otherwise, the voltage is relatively smaller.

As shown in fig. 5, the rf predistorter 150 includes

An error signal generator 146, configured to receive a branch feedforward rf output coupling signal 168, which is output by the rf transmitter 180 and coupled by the second coupler 136, of the rf excitation signal 160 and a branch feedback rf signal 130, which is output by the power amplifier 116 and coupled by the first coupler 124, obtain an equivalent baseband signal input by the feedforward rf signal of the transmitter and an equivalent baseband signal of the feedback rf signal by down-conversion and demodulation processes, respectively, generate an error signal according to a difference in a time domain between the equivalent baseband signal input by the feedforward rf signal 168 and the equivalent baseband signal input by the feedback rf signal 130 or a nonlinear distortion characteristic in a frequency domain, such as adjacent channel leakage power (ACLR), and send the error signal to the predistortion coefficient generator 142;

a predistortion coefficient generator 144 for adaptively updating a predistortion coefficient according to the error signal, and updating the predistortion coefficient by repeatedly calculating a difference in a time domain between an equivalent baseband signal of the input feedforward rf coupling signal 168 and an equivalent baseband signal of the feedback rf signal 130 and substituting an iterative formula until the error signal is reduced and converged, and transmitting the result to the predistortion polynomial generator 142;

the predistortion polynomial generator 142 is controlled by the start signal 162 to be at a high level, and processes the baseband signal after down-conversion, demodulation and low-pass filtering of the feedforward radio frequency coupling signal 168 input before amplification according to the updated predistortion coefficient to obtain a nonlinear polynomial, and sends the nonlinear polynomial to the predistortion generator 148, otherwise, when the start signal 162 is at a low level, the predistortion polynomial generator 142 is in a non-working state;

the predistortion generator 148 performs predistortion processing on the rf excitation signal 160 according to the nonlinear polynomial to obtain the rf predistortion signal 128, and sends the rf predistortion signal 128 to the power amplifier 116.

The power amplifier 116 receives the predistortion signal 128 and power amplifies it to produce a power amplified rf amplified signal 120. In addition, the power amplifier 116 simultaneously feeds back a power-amplified radio-frequency signal power strength indication analog signal (TSSI)126 to the radio-frequency transceiver 170, where the signal is used to detect the strength of the radio-frequency amplified signal of the current frame, and jointly determines the strength or magnitude of the signal to be transmitted of the next frame according to the quality feedback information of the signal received by the remote user, so as to adjust the strength of the signal transmitted of the next frame by setting the corresponding amplification gain value of the transmitting branch, and adjust the voltage value output by the step-up/step-down dc-dc converter 112 according to the area range where the amplification gain is located.

As shown in fig. 5, a more detailed functional block diagram of a system for adjusting the multi-level supply voltage of a power amplifier based on transmitter branch gain settings is shown.

The radio frequency amplified signal output by the power amplifier 116 is processed by the duplexer 122 and then sent to the transmitting antenna 114 for transmission, and the radio frequency signal received from the transmitting antenna 114 is processed by the duplexer 122 and then amplified by the external low noise amplifier 134 and then sent to the radio frequency receiver 190 in the radio frequency transceiver 170; the rf amplified signal output by the pa 116 passes through the first coupler 124, and then a small portion of the feedback rf signal 130 is fed back to the rf predistorter 150, and at the same time, a portion of the feedback rf signal in the small portion is fed back to the rf receiver in the rf transceiver 170 for down-conversion and demodulation, as another option that may be substituted for the predistortion function generator, which has the advantage that the down-conversion and demodulation processing can be performed in the transmit mode of the rf transceiver 170 while the rf receiver 190 is in the idle state, so as to omit the down-converter, the demodulator, and the analog-to-digital converter 152 in the rf predistorter 150 to simplify the system design. The selection described above is controlled by the enable signal 162.

Specifically, the radio frequency transceiver 170 includes a radio frequency receiver 190, a digital signal processing unit 172 and a radio frequency transmitter 180, which are connected in sequence, wherein the radio frequency receiver 190 includes:

the internal low noise amplifier 199 is configured to receive the radio frequency signal 138 sent by the external low noise amplifier 134, further amplify the radio frequency signal, and send the radio frequency signal to the radio frequency switch 196;

the rf switch 196 is configured to receive the rf signal sent by the internal low noise amplifier 199, and also receive the feedback rf signal 130 sent by the coupler 124, and output the feedback rf signal to the down converter 194;

the down converter 194 is configured to receive the radio frequency signal 138 selected by the radio frequency switch 196 or the feedback radio frequency signal 130, receive a local carrier signal with a single frequency sent by the receiving local oscillator 198, output a baseband signal and a high-frequency harmonic signal through the down converter 194 and send the baseband signal and the high-frequency harmonic signal to the receiving baseband 192, where the high-frequency harmonic signal is filtered by the low pass filter at the receiving baseband 192, and the low-frequency baseband signal is sent to the digital signal processing unit 172 through the low pass filter.

The rf transmitter 180 includes:

the transmission baseband 182 is configured to receive the baseband signal processed by the digital signal processing unit 172, perform digital-to-analog conversion, low-pass filtering to remove a high-frequency harmonic signal, and amplify a digital analog baseband signal on the input digital baseband signal, and then send the signal to the upper frequency converter 184;

an up-converter 184, which multiplies or modulates the carrier signal from the transmit local oscillator 188 by the amplified analog baseband signal to shift the up-converted frequency spectrum into a radio frequency signal, and sends the radio frequency signal to a power amplifier driving unit 186;

the power amplifier driving unit 186 is configured to power amplify the radio frequency signal to be used as an output signal of the system transceiver 170, and the output power driving signal of the power amplifier driving unit 186 is sent to the subsequent power amplifier 116 for further power amplification or is subjected to predistortion processing by the radio frequency predistorter 150.

FIG. 6 is a more detailed circuit diagram of the predistortion generator 148 of FIG. 5, the predistortion generator 148 including a delay circuit 310 to implement the delay time τ₁To match the delay produced by the quadrature radio frequency modulator 320;

the quadrature RF modulator 320 is composed of a delay circuit 330, an in-phase multiplier 340, a quadrature multiplier 350, and an adder 360, wherein the delay circuit 330 generates a delay time τ₂Realizing-90-degree phase shift, thereby forming orthogonal branch radio frequency signals; in the quadrature radio frequency modulator 320,the in-phase predistortion polynomial and the quadrature predistortion polynomial are output signals of the polynomial generator 142, and are multiplied by the in-phase multiplier 340 and the quadrature multiplier 350, respectively, and the multiplied outputs are added by the adder 360 and sent to the third coupler 166 to be synthesized and added.

The second coupler 136 couples a small portion of the rf signal to the quadrature rf modulator 320, and the third coupler 166 combines the rf signal output by the adder 360 and the predistortion signal in the third coupler 166, and then sends the combined signal to the power amplifier 116 for power amplification.

Example 2

The utility model discloses a system based on transmitter branch road gain sets up adjusts power amplifier mains voltage, as shown in fig. 4, describe this device under off-line (offline) mode, actually measure power amplifier output signal power value and export transmission signal intensity pilot signal (TSSI)126 with the help of power amplifier, calibrate transmitter branch road gain index and power amplifier output average power value between one-to-one relation, this transmission signal intensity pilot signal (TSSI)126 is the DC voltage to radio frequency RF signal after the power detector rectification, its size is directly proportional with radio frequency RF signal intensity.

It should be noted that the difference between the off-line mode and the on-line mode is that the off-line mode refers to the radio frequency transceiver being in a non-operating state, for example, the device or system being in the factory parameter performance test and parameter calibration stage; and the online mode is that the used device or system is in a working use state, for example, the device or system is in a user use state.

The power measurement unit 618 and the transmitted signal strength model building unit 616 within the dashed box indicate that the unit is only operating and present in the offline mode; after the rf amplified signal 120 output by the power amplifier passes through the first coupler 124, a small portion of the rf signal is fed back to the rf predistorter 150, and meanwhile, the rf amplified signal 120 is sent to the power measurement unit 618, an output end of the power measurement unit 618 is connected to an input end of the transmit signal strength model establishing unit 616, and an output end of the transmit signal strength model establishing unit 616 is connected to an input end of the transmit branch gain searching unit 608 in the rf transmitter 180.

In the off-line mode, the rf transceiver 170 calibrates the transmitter branch gain index as shown in fig. 4 and 5, and the rf transmitter includes:

an analog-to-digital converter (ADC)602, configured to receive and convert the rf signal power strength indication analog voltage signal 126 amplified by the power amplifier 116, and send a converted digital signal to the gain index control unit 604;

a gain index control unit 604, configured to calibrate the actually measured transmit power and the target power in an offline mode before the system device leaves a factory, so that an error between the actually measured transmit power and the target power is smaller than a threshold value, and set a corresponding gain index as an output to respectively control the transmit branch gain search unit 608 and the control index simplification unit 606;

a transmitting branch gain searching unit 608, configured to receive the gain index output by the gain index control unit 604, allocate power amplification times or gains of each circuit in the transmitting branch circuit unit in a table lookup manner, and output a signal to set the transmitting branch circuit unit 614 to control a corresponding power gain value of each circuit;

a transmitting branch circuit unit 614, configured to set a corresponding power gain value of each circuit according to the power amplification factor or gain of each circuit of the transmitting branch distributed by the transmitting branch gain searching unit 608, so as to determine the power of the radio frequency excitation signal at the input end of the radio frequency predistorter; the transmit branch circuit unit 614 includes a second digital-to-analog converter (DAC), an analog low pass filter, an analog baseband signal amplifier, in-phase and quadrature branch modulators, and a power amplifier driver, wherein the analog filter is located at the output of the second digital-to-analog converter (DAC) and functions to remove high frequency components and smooth its input waveform to remove spurious high frequency copies or "images"; the modulator uses the amplified input baseband signal to modulate, i.e. multiply, a carrier signal, which is also called frequency uplink conversion, the modulated modulation signal realizes spectrum shifting, i.e. a low-frequency spectrum is shifted to a high-frequency spectrum, and the up-converter and the modulator are designed together to realize the spectrum shifting; the radio frequency power amplification driver is used for amplifying the power of the modulated signal to meet the requirement of the following power amplifier on the power of the input signal of the power amplifier, the amplification gain of the amplification driver is adjustable, and the output signal power of the power amplifier can be increased or decreased through adjustment.

The transmitting branch circuit unit 614 mainly comprises an analog circuit, including a baseband signal circuit and a radio frequency signal circuit.

A control index simplifying unit 606, configured to receive the gain index output by the gain index control unit 604, perform simplification processing on the gain index to obtain a simplified control index, and send the simplified control index to the power supply voltage searching unit 610;

the power supply voltage searching unit 610 is configured to find a corresponding power supply voltage value according to the received simplified gain index, and convert the power supply voltage value into an analog voltage signal through a first digital-to-analog converter (DAC)612 to control the step-up/step-down dc-dc converter 112 to output a corresponding multi-level power supply voltage as the power amplifier power supply voltage value.

The gain setting of the transmitting branch is realized by setting the amplification gain of each circuit in the transmitting branch unit, and the purpose of the gain setting is to adjust the power of the rf amplified signal 120 output by the power amplifier 116, and the following table lists a distribution relationship between the gain index of the transmitting branch and the amplification gain of each circuit unit. The sum of the amplified gain decibel (dB) of each circuit unit is equal to the gain decibel (dB) of the transmitting branch, the output power decibel milliwatt of the power amplifier is equal to the input power decibel milliwatt of the low-pass filter plus the gain decibel of the transmitting branch, and the gain decibel of the power amplifier is added. For example, at a gain index h of 50, the power amplifier output power is equal to P_IN(dBm)+15(dB)+25(dB)＝P_IN+40(dBm)。

Table for generating amplification gain configuration of each circuit unit in a transmitting branch and table for relation between the amplification gain configuration and output power of power amplifier

In the off-line mode, the working mode of gain index calibration is as follows:

first, a target power decibel-milliwatt (dBm) value output by the power amplifier is preset, and then, an amplification gain index is set by the gain index control unit 604, where the gain index corresponds to an estimated amplification gain value of the transmit branch, and the amplification gain value is equal to the sum of the amplification gain decibel values of each circuit in the transmit branch circuit unit 614, as shown in fig. 5. Then, the output gain index signal according to the index control unit 604 is sent to the transmission branch gain searching unit 608 to search out the pre-designed amplification gain distribution format of each circuit, and the gain distribution format is sent to the transmission branch circuit unit 614 to set the amplification gain value of each circuit unit. The above-mentioned amplification gain index setting is expected to make the difference between the measured power obtained at the output terminal of the power amplifier and the target power in decibel-milliwatt (dBm) smaller than a specific threshold value, whereas the difference between them is made smaller than the specific threshold value by repeatedly adjusting the gain index h in the gain index control unit 604.

The output voltage value of the step-up/down dc-dc converter 112 depends on the analog voltage signal input by the step-up/down dc-dc converter, and the power amplifier supply voltage is directly set or adjusted by the step-up/down dc-dc converter according to the region where the transmitter branch gain index is located, and is used as the power amplifier supply voltage when transmitting the next frame of radio frequency signals, and the power supply voltage value is set before the next frame of transmission signals and is stabilized when transmitting the next frame of signals. In this way, the analog voltage signal can be modified according to the number of the area divisions of the control coefficient reduction unit 606 to meet the actual application requirements.

The utility model discloses the relation that well power amplifier mains voltage set value is strong and weak at each frame signal waveform with 802.11 wireless area network radio frequency signal is shown in figure 7, and its each frame signal waveform is strong and weak directly proportional with the average power of this frame signal. Ttx is the time that the radio frequency transceiver 170 transmits a frame signal transmission to the subscriber in the transmit mode, and Trx is the time that the radio frequency transceiver receives an acknowledgement from the subscriber that it has received correctly in the receive mode of 170. It can be seen from fig. 7 that the power amplifier supply voltage is proportional to the average power of the power amplifier output signal by the gain setting of the transmitting branch (see fig. 5 in detail), i.e. as the average power value of the signal per frame increases or decreases, the supply voltage also increases or decreases. When the average power of the transmitted signals per frame is reduced, the direct current power consumption is reduced along with the reduction of the power supply voltage, thereby improving the energy efficiency without causing the distortion of the radio frequency signals. The reason why the DC power consumption is reduced by reducing the redundant DC power consumption and the RF signal is not distorted is that the power supply voltage is set to be stable before the next frame signal is transmitted and the voltage is proper in size, so that the transmission signal is not distorted.

The method comprises the steps of calibrating and selecting 3 representative frequency points in a transmission frequency bandwidth, namely, a lowest end channel center frequency point, a middle end channel center frequency point and a highest end channel center frequency point, wherein the relationship is determined between the power or the strength of an output signal of a power amplifier and a transmitter branch gain index in an off-line state before leaving a factory, and the channel center frequency points are selected to be related to the transmission signal bandwidth. Firstly, selecting a point of a central frequency point of a low-end channel to calibrate the determined relation between the power or strength of the output signal of the power amplifier and the gain index of the transmitter branch, adjusting the gain index of the transmitter branch from small to large and the power step length to be about 0.5 decibel, and measuring the power of the output signal of the power amplifier under each gain index setting, thereby recording the relation between all the gain indexes and the measured power. And then repeating the steps to respectively calibrate the determined relation between the power of the output signal of the power amplifier and the gain index of the transmitter branch at the central frequency point of the middle-end channel and the central frequency point of the highest-end channel, and adjusting the gain index at each frequency point until the error between the output power of the actually-measured radio frequency transmitter and the target power is less than or equal to +/-1 decibel.

The calibrated gain index is stored in a memory in the radio frequency transceiver and used for setting the gain of a transmitting branch circuit to complete the output of required transmitting power by adjusting the gain index according to the output power required by the next frame in an on-line working mode, and simultaneously finding out the corresponding power supply voltage value according to the simplified gain index, and converting the power supply voltage value into an analog voltage signal through a digital-to-analog converter to control a voltage boosting/reducing DC-DC converter to output the corresponding voltage level as the power supply voltage value of a power amplifier.

As shown in fig. 8, the embodiment 1-2 of the present invention extracts the rf predistortion coefficient for the power amplifier working under different power voltages by respectively collecting the input and output equivalent baseband signals of the power amplifier in the offline mode.

The system comprises a radio frequency signal generator 510, a voltage boosting/reducing DC-DC controller 506, a voltage boosting/reducing DC-DC converter 112, a power amplifier 116, an attenuator 514, a spectrum analyzer 516 and a computer 504, wherein when the power amplifier outputs equivalent baseband signals, the output end of the radio frequency signal generator 510 is connected with the power amplifier 116, the attenuator 514, the spectrum analyzer 516 and the computer according to 504 times, and when the power amplifier inputs equivalent baseband signals, the output end of the radio frequency signal generator 510 is connected with the spectrum analyzer 516 and the computer according to 504 in sequence. The step-up/down dc-dc controller 506 outputs an analog voltage signal to control the output voltage of the step-up/down dc-dc converter 112, which is the power supply voltage of the power amplifier 118.

It should be noted that the input terminal of the signal connected to the spectrum analyzer 516 via the solid line is used for collecting the output signal data of the power amplifier 116, and the input terminal connected to the spectrum analyzer via the dotted line is used for collecting the input signal data of the rf signal generator 510 as the input signal data of the power amplifier 116, and these two different ways of connecting to the input terminal of the spectrum analyzer 516 are not performed simultaneously, but are connected separately for collecting different signal data.

Wherein the rf signal generator 510 outputs the modulated rf signal for a specific application for the input signal of the power amplifier 116 and is amplified by the power amplifier, in order to reflect the non-linear characteristic of the power amplifier, the input signal strength of the power amplifier should be strong enough to enable the power amplifier to operate in the non-linear region or close to the non-linear region. The amplified rf signal is attenuated by the attenuator 514, and then sent to the spectrum analyzer 516 for down-conversion, filtering, and demodulation, so as to finally obtain an equivalent baseband signal output by the rf signal of the power amplifier, and output to the computer 504 for digital signal analysis and processing, which is called power amplifier output signal acquisition.

Then, the rf signal generator 510 is connected to the input of the spectrum analyzer 516 without passing through the power amplifier, and the down-conversion, filtering and demodulation processes as described above are performed to obtain the rf signal input equivalent baseband signal of the power amplifier, and then the equivalent baseband signal is output to the computer 504 for digital signal analysis and processing, which is called power amplifier input signal acquisition.

The acquired input and output baseband signals are digitally processed by a computer, for example, by up-converting the low sample rate data using interpolation, cross-correlating the input and output signals in the time domain to align them, and truncating the appropriate data length, after which the equal length input and output data are substituted into a least squares (least square) formula to solve the predistortion coefficients at the supply voltage.

Next, the step-up/step-down dc-dc converter 112 is adjusted to the next output power voltage by the step-up/step-down dc-dc controller 506, and the above data acquisition process is repeated to solve the predistortion coefficients at the voltage until all different but limited sets of predistortion coefficients excited by a plurality of voltage values are solved, and all the different sets of predistortion coefficients are stored in a predistortion coefficient search unit in the radio frequency transceiver, for example, the predistortion coefficient generator 144 in fig. 3 and 5, as initial predistortion coefficient sets at different voltage values. When the transceiver works in an on-line mode, the initial value of the corresponding predistortion coefficient set is read out according to the preset value of the power supply voltage, a predistortion polynomial is generated, and a radio frequency predistortion signal is generated through the predistorter.

In the off-line mode, in which the power amplifier is operated under different power supply voltage excitations as shown in fig. 9 and referring to fig. 8 at the same time, the method of extracting the corresponding Radio Frequency Predistortion (RFPD) coefficient as the initial coefficient value includes:

step 810: the boost/buck controller 506 sets the limited number N of the power supply voltages, and the ith voltage value Vi, i is greater than or equal to 1 and less than or equal to N;

step 820: if i is 1, the power supply voltage vi of the power amplifier is V_CCThat is, the power supply voltage of the power amplifier is the first fixed voltage V of the conventional power amplifier_CCOtherwise, Vi is Vi, i is more than or equal to 1 and less than or equal to N, and then a predistortion coefficient corresponding to the ith voltage value is calculated;

step 830: firstly, an orthogonal frequency division multiplexing radio frequency signal (OFDM) generated by a radio frequency signal generator is connected to a spectrum analyzer, the spectrum analyzer 516 performs frequency down-conversion, analog-to-digital conversion and demodulation processing on the input OFDM radio frequency signal, and the processed baseband signal is used as a power amplifier radio frequency input equivalent baseband signal and is output to a computer;

step 840: then, the orthogonal frequency division multiplexing radio frequency signal generated by the radio frequency signal generator is output to the input end of the power amplifier 116 for power amplification processing, the amplified radio frequency signal is sent to the spectrum analyzer 516 through the attenuator for frequency down-conversion, demodulation and analog-to-digital conversion processing, and the baseband signal after the analog-to-digital conversion processing is used as the power amplifier output equivalent baseband signal and is output to the computer;

step 850: the computer processes the digital signals of the acquired radio frequency input equivalent baseband signal and the acquired output equivalent baseband signal of the power amplifier, and then substitutes the signals into a least square method formula to solve a predistortion polynomial coefficient which is used as an initial coefficient group of Vi ═ Vi under the condition that i is more than or equal to 1 and is less than or equal to N,

step 860: continuously calculating the predistortion coefficient corresponding to the (i + 1) th voltage value, wherein i is equal to i +1, judging whether i is greater than N, and if i is less than N, continuously repeating the step 820 and 850; if i is larger than N, entering the next step;

step 870: and storing the predistortion coefficient groups corresponding to the i voltage values at the solved positions in a polynomial coefficient table corresponding to different voltage values in the radio frequency transceiver for storage, wherein the polynomial coefficient table is used for working in a predistortion initial coefficient group in an online mode.

In an off-line mode, the power amplifier is excited by different power supply voltages, and corresponding predistortion coefficient groups are solved by collecting data of radio frequency input equivalent baseband signals and output equivalent baseband signals of the power amplifier and substituting the data into a least square method formula respectively. When the transmitter in the transceiver works in an on-line mode, the gain region of the size of the transmission signal of the next frame is set according to the transmission branch circuit, the power supply voltage of the power amplifier is correspondingly adjusted, and meanwhile, a corresponding predistortion initial coefficient group is read out from a table look-up data table in the transmitter and is used for compensating nonlinear distortion generated by the power amplifier under the excitation of the power supply voltage. The table lookup data table is configured to store sets of predistortion coefficients, as described in step 870 above.

As shown in fig. 5, the rf predistorter 150 adaptively updates predistortion coefficients in an online mode, and a process for compensating for nonlinear distortion caused by the power amplifier 116 under different supply voltages includes:

step S1: the error signal generator 146 collects a feedforward radio frequency signal 168 of a radio frequency excitation signal output by the radio frequency transceiver 170 and coupled by the second coupler and a feedback radio frequency signal 130 of a radio frequency amplification signal output by the power amplifier 116 and coupled by the first coupler, respectively performs down-conversion and demodulation processing to obtain an equivalent baseband signal input by the feedforward radio frequency signal and an equivalent baseband signal of the feedback radio frequency signal, generates an error signal by using the difference between the equivalent baseband signals of the feedforward radio frequency signal and the feedback radio frequency signal in a time domain, or obtains the error signal according to the strength of a leakage signal outside a frequency domain of the equivalent baseband signal of the feedback radio frequency signal, and then substitutes the error signal into an adaptive algorithm to update a predistortion coefficient;

step S2: sending the predistortion coefficients updated in step S1 to the predistortion polynomial generator 142 to generate a predistortion polynomial, and sending the predistortion polynomial to the predistortion generator 148, the predistortion polynomial including in-phase component and quadrature component polynomials and both having nonlinear characteristics;

step S3: in the predistortion generator, the in-phase component of the predistortion polynomial is multiplied by the in-phase signal of the input radio frequency excitation signal, and the quadrature component of the predistortion polynomial is multiplied by the quadrature signal of the input radio frequency excitation signal; the results of the two calculations are then added to produce the desired radio frequency predistortion signal.

The above is only the preferred embodiment of the present invention, and is not intended to limit the present invention, and at the same time the present invention uses the radio frequency transceiver system in the IEEE 802.11 wireless local area network as the application example of the present invention, but is not limited to this system. Any simple modifications, changes and equivalent changes made to the above embodiments according to the technical spirit of the present invention all fall within the protection scope of the technical solution of the present invention.

Claims (6)

1. A system for adjusting a power amplifier supply voltage based on a transmitter branch gain setting, the system comprising

The radio frequency transceiver comprises a radio frequency transmitter and a radio frequency receiver, wherein the radio frequency transmitter is used for outputting an analog voltage signal to control the output variable multilevel power supply voltage value of the step-up/step-down DC-DC converter to serve as the power supply voltage of the power amplifier, and outputting a radio frequency excitation signal to the radio frequency predistorter for predistortion processing;

the boost/buck direct current-direct current converter is used for receiving the analog voltage signal output by the radio frequency transmitter and converting the input direct current voltage of the boost/buck direct current-direct current converter into a corresponding voltage value in multi-level power supply voltage as output voltage to provide the power supply voltage value for the power amplifier;

the radio frequency predistorter is used for receiving a radio frequency excitation signal output by the radio frequency transmitter, carrying out predistortion processing on the radio frequency excitation signal to obtain a radio frequency predistortion signal, and outputting the radio frequency predistortion signal to the power amplifier; the receiving circuit is also used for receiving a branch circuit feedback radio frequency signal of a radio frequency amplified signal of the power amplifier coupled by the first coupler and receiving a branch circuit radio frequency signal of a radio frequency excitation signal output by the radio frequency transmitter coupled by the second coupler;

the power amplifier is used for receiving the multi-level power supply voltage and the radio frequency predistortion signal, amplifying the radio frequency predistortion signal under different variable power supply voltages, sending the amplified radio frequency predistortion signal to the antenna as a radio frequency amplification signal, and feeding back a branch signal of the radio frequency amplification signal to the radio frequency predistorter after being coupled by the first coupler; and the power strength indication analog voltage signal of the radio frequency amplification signal is fed back to the radio frequency transceiver.

2. The system of claim 1 wherein the boost/buck dc-to-dc converter output voltage is controlled by the converter input analog voltage for the next frame transmit signal, the input analog voltage being adjusted by the transmit branch gain setting in the radio frequency transmitter, the boost/buck dc-to-dc converter output voltage being used as the power amplifier supply voltage during the next frame transmit signal.

3. The system for adjusting power amplifier supply voltage based on transmitter branch gain setting of claim 1, wherein the radio frequency predistorter comprises

The error signal generator is used for receiving a branch feedforward radio-frequency signal which is output by the radio-frequency transmitter and coupled by the second coupler and a branch feedback radio-frequency signal which is output by the power amplifier and coupled by the first coupler, respectively obtaining an equivalent baseband signal of the feedforward radio-frequency signal and an equivalent baseband signal of the feedback radio-frequency signal through down-conversion and demodulation processing, generating an error signal according to the difference of the equivalent baseband signal of the input feedforward radio-frequency signal and the equivalent baseband signal of the feedback radio-frequency signal in a time domain or a frequency domain, and sending the error signal to the predistortion coefficient generator;

the predistortion coefficient generator adaptively updates the predistortion coefficient according to the error signal until the error signal is reduced and converged, and sends the predistortion coefficient to the predistortion polynomial generator;

the predistortion polynomial generator is used for processing the baseband signal after the input feedforward radio frequency signal is subjected to down-conversion, demodulation and low-pass filtering according to the updated predistortion coefficient to obtain a nonlinear polynomial and sending the nonlinear polynomial to the predistortion generator;

and the predistortion generator is used for processing the radio frequency excitation signal according to the nonlinear polynomial to obtain a radio frequency predistortion signal and sending the radio frequency predistortion signal to the power amplifier for power amplification.

4. The system for adjusting power amplifier supply voltage based on transmitter branch gain setting of claim 1, wherein said radio frequency transmitter comprises

The analog-to-digital converter is used for receiving and converting the radio frequency signal power strength indication analog signal amplified by the power amplifier and sending the converted digital signal to the gain index control unit;

the gain index control unit is used for calibrating the actually-measured transmitting power and the target power through an off-line mode before the system leaves a factory so that the error between the actually-measured transmitting power and the target power is smaller than a threshold value, and setting a corresponding gain index as an output to respectively control the transmitting branch gain searching unit and the control index simplifying unit;

the transmitting branch circuit unit is used for receiving the gain index output by the gain index control unit, distributing the power amplification factor or gain of each circuit in the transmitting branch circuit unit in a table look-up mode, and outputting a signal to set the corresponding power gain value or amplification factor of each circuit controlled by the transmitting branch circuit unit;

the transmitting branch circuit unit is used for setting corresponding power gain values of all circuits according to the power amplification times or gains of all circuits of the transmitting branch distributed by the transmitting branch gain searching unit, so that the power of the radio frequency excitation signal at the input end of the radio frequency predistorter is determined;

the control index simplifying unit is used for receiving the gain index output by the gain index control unit, carrying out simplification processing on the gain index to obtain a simplified control index, and sending the simplified control index to the power supply voltage searching unit;

and the power supply voltage searching unit is used for searching out a corresponding power supply voltage value according to the received simplified gain index, and converting the power supply voltage value into an analog voltage signal through the first digital-to-analog converter to control the step-up/step-down DC-DC converter to output a corresponding voltage level as the power supply voltage value of the power amplifier.

5. The system for adjusting power amplifier supply voltage based on transmitter branch gain setting of claim 4, wherein the transmit branch circuit unit comprises a second digital-to-analog converter, an analog filter, an amplifier, a modulator, an up-converter, and a radio frequency power amplification driver;

the second digital-to-analog converter converts the digital baseband signal into an analog baseband signal, and the analog filter is positioned at the output end of the second digital-to-analog converter and is used for removing high-frequency components; the amplifier properly amplifies the filtered baseband signal, and the amplification gain of the amplifier is used as a part of the gain of the transmitting branch circuit; the modulator modulates the carrier signal by using the amplified input baseband signal, the modulated modulation signal realizes spectrum shifting, namely, a low-frequency spectrum is shifted to a high-frequency spectrum, and the up-converter and the modulator are designed together to realize spectrum shifting; the radio frequency power amplification driver is used for carrying out power amplification on the modulated modulation signal so as to meet the requirement of a following power amplifier on the power of an input signal of the power amplifier, the amplification gain of the power amplifier is fixed, the amplification gain of the radio frequency power amplification driver is adjustable, and the output signal power of the power amplifier can be increased or reduced by adjusting;

the sum of the power gains decibel of the analog filter, the amplifier, the modulator, the up-converter and the radio frequency power amplification driver forms the gain decibel of the transmitting branch, and the sum of the gain decibel of the transmitting branch and the gain of the power amplifier jointly determines the output power of the power amplifier.

6. The system of claim 3, wherein the system for adjusting the power supply voltage of the power amplifier based on the gain setting of the transmitter branch comprises a radio frequency signal generator, a boost/buck DC-DC controller, an attenuator, a spectrum analyzer, and a computer, wherein the output of the radio frequency signal generator is connected to the power amplifier, the attenuator, the spectrum analyzer, and the computer in sequence for collecting the output signal of the power amplifier, the output of the radio frequency signal generator is also directly connected to the spectrum analyzer for collecting the input signal of the power amplifier, and the boost/buck DC-DC controller outputs an analog voltage signal for controlling the boost/buck DC-DC controller to output the analog voltage signal The output voltage of the converter, which is the supply voltage of the power amplifier.

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