KR20010084642A - Feeforward Linearizer with Auto Gain Control Loop - Google Patents

Abstract

According to an aspect of the present invention, there is provided a feedforward linearizer having an automatic gain adjuster, comprising: a signal amplifier for amplifying an input signal and removing distortion of the amplified input signal, a first input unit for receiving the input signal; Attenuation gain of the input signal is obtained by comparing a difference between the second input unit receiving the output signal of the signal amplifying unit and the received strengths of the signals inputted to the first input unit and the second input unit with a reference amplification unit of the signal amplifying unit. It is configured to include a control unit for generating a control signal for controlling, and has the effect of obtaining a stabilized gain and linearization by removing the deterioration of the temperature, component degradation and gain by using an automatic gain control loop.

Description

Feedforward Linearizer with Auto Gain Control Loop}

The present invention relates to a feedforward linearizer, and more particularly to a feedforward linearizer having an automatic gain adjuster.

In general, when a single frequency input signal is applied to a large power amplifier, the output gain decreases and the phase delay occurs as the size of the input signal increases due to AM-to-AM or AM-to-PM conversion. In addition, when signals having various frequencies are input, intermodulated distortion signal components having different nonlinear propagation characteristics are generated in addition to an output signal having the same frequency as the input signal.

The conventional feedforward method is a method of improving linear characteristics by extracting only intermodulation distortion components from the output of the amplifier and combining them back to the output of the amplifier. This method is more effective than other methods, but the circuit is complicated and the linear characteristics of these changes are greatly deteriorated because they are sensitive to temperature changes, operating range changes, and frequency changes.

1 is a block diagram showing a linearizer of a conventional feedforward method.

As shown in FIG. 1, the signal amplifying unit includes a main path (1), an error correction path (2), and a divider (3).

The main path of the signal (Main Path: 1) consists of a main amplifier (Main Amp: 6), a delay line (Delay Line: 8) for delay compensation, and an Error Correction Path (2). Is composed of a variable attenuator 11, a variable phase shifter 12, a subtraction circuit 13, an error correction amplifier 10, and a delay line 14.

The carrier applied to the input is divided by the divider 3 with the same magnitude and phase as the main path 1 and the error correction path 2, as shown in FIG.

In the main pass (1) is amplified to the desired output level by the main amplifier (6), which is a large power amplifier to generate intermodulation distortion signals together. If some of the carrier and intermodulation distortion components are extracted from this output and applied to the subtraction circuit 13, only the pure carrier is input to the subtraction circuit 13 in the error correction path 2, and therefore the intermodulation circuit is output at the subtraction circuit 13 output. Only distortion signals are obtained. The intermodulation distortion signal components obtained at the output of the subtraction circuit 13 are coupled back to the main path 1 via a variable phase shifter 12, a variable attenuator 11, and an error correction amplifier 10. .

At this time, the variable attenuator 11 is for adjusting the level of the intermodulation distortion signal appearing in the main amplifier 6, which is a power amplifier, and the variable phase converter 12 is inverse of 180 ° when coupled to the main path 1 again. To match the phase. In this way, the magnitude of the intermodulation signal coupled back to the main path 1 is out of phase with the intermodulation distortion component generated by the main amplifier 6, leaving only the pure carrier at the final output.

The feedforward linearizer according to the related art described above has a problem that it is difficult to maintain a constant gain and linearization characteristics for such a change because it is sensitive to temperature change and component deterioration.

Accordingly, an object of the present invention is to provide a stable gain and linear characteristics by adding an automatic gain control loop circuit to a signal amplifying part of a linearizer.

Features of the feedforward linearizer having an automatic gain adjuster according to the present invention for achieving the above object is a signal amplifier for amplifying an input signal and removing the distortion of the amplified input signal and outputs the input signal; Comparing the difference between the received intensity of each signal input to the first input unit, the second input unit receiving the output signal of the signal amplification unit, and the first input unit and the second input unit by comparing with the reference amplification degree of the signal amplification unit And an operation unit for generating a control signal for controlling the attenuation gain of the input signal.

And a temperature sensor that measures a temperature of each device for controlling the input signal and provides a calculating unit with difference information between the measured temperature and the reference temperature.

The first input unit and the second input unit respectively include an attenuator for adjusting an input signal and an output signal to a predetermined size, a filter for removing noise of the adjusted input signal and an output signal, and the noise canceled signal of the And a received signal strength measuring device for measuring a received signal strength (RSSI) voltage and inputting it to the calculating part.

An operation according to a feature of the present invention is to add an automatic gain control section having an operation section to a conventional feedforward linearizer, the voltage of the input signal, the voltage of the output signal, and the temperature sensor measured by the automatic gain control loop. Since a predetermined signal is adjusted by generating a control signal for calculating the difference between voltages and controlling the gain, a stabilized gain and linearization can be obtained by eliminating temperature, component degradation, and gain instability.

1 is a block diagram showing a linearizer of a conventional feedforward method.

2 is a block diagram illustrating a feedforward linearizer having an automatic gain adjuster in accordance with the present invention.

Explanation of symbols for main parts of the drawings

1: Main Pass 2: Error Correction Pass

3: divider 4, 11, 16, 21, 22: variable attenuator

5, 12: variable phase shifter 6: main amplifier

7, 9, 15: directional coupler 8, 14: delay line

10: error correction amplifier 13: subtraction circuit (combiner)

17, 23: bandpass filter

18, 24: Log Detector / RSSI

19: calculator 20: temperature sensor

30: automatic gain control unit (AGC) 31: first input unit

32: second input unit

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of a feedforward linearizer having an automatic gain adjuster according to the present invention will be described with reference to the accompanying drawings.

2 is a block diagram illustrating a feedforward linearizer having an automatic gain adjuster according to the present invention, and includes a signal amplifier and an automatic gain adjuster 30 for amplifying an input signal and outputting the amplified input signal by removing distortion. do.

The signal amplifier includes a main path 1, an error correction path 2, and a divider 3, and the automatic gain control unit 30 includes a first input unit 31 that receives the input signal, The difference between the second input unit 32 receiving the output signal of the signal amplifying unit and each of the signals input to the first input unit and the second input unit is calculated by comparing the reference amplification unit with the reference amplification unit of the input signal. And a computing section for generating a control signal for controlling the attenuation gain, and a variable attenuator 21 input to the signal amplifier according to the generated control signal. And it further comprises a temperature sensor 20 for measuring the temperature of each device for the control of the input signal, and providing the difference information between the measured temperature and the reference temperature to the calculation unit.

The automatic gain control unit 30 calculates the difference between each input signal voltage and the output signal voltage, the difference between the output signal voltage and the voltage of the temperature sensor 20, and the difference between the input signal voltage and the voltage of the temperature sensor 2. Computation is performed by the negation operator 19, and the gain is constantly adjusted by the variable attenuator 21 according to the calculated difference.

As shown in FIG. 2, the carrier applied to the input has the same magnitude and phase, and extracts a part of the amplified signal from the main path 1 and the main path 1 that input and amplify the signal to obtain a distorted signal. The divider 3 divides the error correction path 2 to be output.

In the main fes 1, the main amplifier 6, which is a large power amplifier, is amplified to a desired output level and also generates intermodulation distortion signals. In this output, the carrier and the intermodulation distortion components are partially extracted and applied to the subtraction circuit 13 for canceling the signal. In the error correction path 2, only the pure carrier is input to the subtraction circuit 13, so the subtraction circuit 13 At the output) only intermodulation distortion signals are obtained.

The intermodulation distortion signal components obtained at the output of the subtraction circuit 13 are coupled back to the main path 1 via a variable phase shifter 12, a variable attenuator 11, and an error correction amplifier 10. . At this time, the variable attenuator 11 is for adjusting the level of the intermodulation distortion signal appearing in the main amplifier 6, which is a power amplifier, and the variable phase shifter 12 is inverse of 180 ° when coupled to the main path 1 again. To match the phase.

In this way, the magnitude of the intermodulation signal coupled back to the main path 1 is out of phase with the intermodulation distortion component generated by the main amplifier 6, leaving only the pure carrier at the final output.

The transmit input signal passes through a divider (3) and is adjusted by the second input unit 32 to the variable attenuator 22 to a predetermined size, and then a band pass filter to remove out-band noise. The bandpass filter 23 is inputted to the calculator 19 using a log detector / RSSI 24 to measure a received signal strength (RSSI) voltage according to a change in a transmission input signal.

The transmit output signal is then radiated through the directional coupler 15, passed through a 30 dB coupler, adjusted by the first input 31 to a constant magnitude via the variable attenuator 16, and then out band noise is removed. In order to measure the received signal strength (RSSI) voltage according to the change of the transmission output signal through a bandpass filter (17), it is input to the calculator 19 which is an operation unit using a log detector / RSSI 18. .

Automatic gain control of the variable attenuator 21 in the transmission input signal amplification unit by the difference between the transmission input received signal strength (RSSI) voltage and the transmission output received signal strength (RSSI) voltage input to the calculator 19. To have a constant gain. That is, if the difference is greater than the reference amplification degree of the main amplifier 6, the attenuation gain of the variable attenuator 21 is increased, and if the difference is less than the reference amplification degree, the attenuation gain of the variable attenuator 21 is decreased to determine the transmission input signal to the output signal. The gain ratio is made constant.

In addition, in order to minimize the temperature difference according to the temperature change, the temperature sensor 18 is applied to input the voltage according to the temperature change to the calculator 19. The calculator 19 adjusts the variable attenuator 21 after calculating the change in the received signal strength (RSSI) voltage of the transmission output signal and the voltage of the temperature sensor (Temperature Sensor) 20, and then changes the temperature, component deterioration, and gain. By applying the automatic gain compensation circuit (AGC) according to obtain a constant gain. In other words, if the difference is greater than the reference value, the attenuation gain of the variable attenuator 21 is increased, and if the difference is less than the reference value, the attenuation gain of the variable attenuator 21 is decreased, so that the gain of the transmission input signal to the output signal regardless of the change in the temperature of the circuit. Keep the rain constant

In addition, the voltage according to the temperature change and the voltage of the received signal strength of the transmission input signal is input to the calculator 19, and the variable attenuator 21 is adjusted after the calculation to adjust the automatic gain compensation circuit according to the temperature, component deterioration, and change in gain. Apply (AGC) to get a constant gain. That is, if the difference is larger than the reference value, the attenuation gain of the variable attenuator 21 is increased. If the difference is smaller than the reference value, the attenuation gain of the variable attenuator 21 is decreased to increase the gain ratio of the transmission input to output regardless of the change in the temperature of the circuit. Make it constant.

The feedforward linearizer having the automatic gain adjuster according to the present invention as described above has an effect of obtaining a stabilized gain and linearization by compensating for gain instability due to temperature and component deterioration using an automatic gain control loop.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (3)

A signal amplifier for amplifying an input signal and removing and outputting distortion of the amplified input signal; A first input unit configured to receive the input signal; A second input unit configured to receive an output signal of the signal amplifier; And a calculation unit configured to generate a control signal for controlling attenuation gain of the input signal by comparing the difference in the received strengths of the signals inputted to the first input unit and the second input unit with a reference amplification unit of the signal amplifier. A feedforward linearizer having an automatic gain adjuster. The automatic gain adjuster of claim 1, further comprising a temperature sensor configured to measure a temperature of each device to control the input signal, and provide a calculation unit with a difference information between the measured temperature and the reference temperature. Branch feed forward linearizer. The method of claim 2, wherein the first input unit and the second input unit An attenuator for adjusting an input signal and an output signal to a predetermined size, respectively, A filter for removing noise of the adjusted input signal and output signal, And a received signal strength measurer measuring the received signal strength (RSSI) voltage of the noise-removed signals and inputting them to the calculator.