KR100790122B1 - Circuit and method for compensating non-linear distortion - Google Patents

Abstract

The present invention relates to circuits and methods for compensating for nonlinear distortions. According to the present invention, a nonlinear distortion component is extracted from a nonlinear high output amplified modulated signal, and an inverse phase distortion component of a distortion component of a baseband region generated by orthogonal demodulation of the extracted distortion component is converted into a baseband region. Nest in. After the orthogonal modulation of the baseband signal superimposed with the inverse distortion component, nonlinear high power amplification eliminates nonlinear distortion generated during nonlinear high power amplification.

By the above processing process, nonlinear distortion due to high power amplification can be compensated with high accuracy without using complicated and large-scale digital arithmetic circuits or pseudo distortion generating circuits, etc., and since the circuit scale is small, power consumption can be reduced. have.

Nonlinear Distortion, Distortion Compensation, High Power Amplification

Description

Nonlinear Distortion Compensation Circuit and Nonlinear Distortion Compensation Method {CIRCUIT AND METHOD FOR COMPENSATING NON-LINEAR DISTORTION}             

1 is a circuit diagram showing the configuration of a nonlinear distortion compensation circuit according to a first embodiment of the present invention;

2 is a flowchart illustrating a processing procedure according to an embodiment of the distortion compensation method of the present invention;

3 is a characteristic diagram showing an operation confirmation result by a calculator simulation of the circuit shown in FIG. 1;

4 shows a characteristic curve of output power according to ACPR vs. input level characteristic;

FIG. 5 is a circuit diagram showing a specific configuration example for configuring the phase adjuster shown in FIG. 1; FIG.

6 is a circuit diagram showing the configuration of a nonlinear distortion compensation circuit according to a second embodiment of the present invention;

7 is a diagram showing a configuration example of a transmitter equipped with a nonlinear distortion compensation circuit according to a predistortion scheme;                 

8 is a diagram showing an example of the configuration of a transmitter equipped with a nonlinear distortion compensation circuit according to a predistortion scheme using a feedback value.

<Description of Major Symbols in Drawing>

11. Orthogonal Modulator

12, 14... Directional Coupler or Divider

13. HPA (High Power Amplifier)

15... Attenuator

16, 23, 24... Subtractor

17. Delay circuit or abnormal phase

18. Orthogonal Demodulation

19. Phase adjuster

20, 25... Carrier Generator

21, 22... Amplitude regulator

111, 181... π / 2 or more phase

114. adder

112, 113, 182, 183... Multiplier

The present invention relates to an orthogonal modulation circuit and an orthogonal modulation method used in a wireless transmitter, and more particularly, to a nonlinear distortion compensation circuit and a nonlinear distortion compensation method for compensating for nonlinear distortion generated when high power amplification is performed after orthogonal modulation of a baseband signal. will be.

In general, a radio transmission circuit spreads a signal to be transmitted in an orthogonal modulation circuit. The spread signal is orthogonally modulated with the baseband signal, and then amplified and transmitted with high power. This high power amplification is used to improve power efficiency. At this time, the amplification characteristic of the high power amplification has a nonlinear amplification characteristic. Therefore, since nonlinear distortion occurs in the amplified modulated signal, the input and output characteristics should be linearized by compensating for the generated distortion.

As a method of compensating the nonlinear distortion, there is a nonlinear distortion compensation method of a predistortion method. The predistortion circuit is shown in FIG. 7. Next, the predistortion scheme will be described with reference to FIG. 7.

The baseband signals I and Q are calculated by the distortion compensation calculator 1 and input to the D / A converters 2 and 3. The D / A converters 2 and 3 convert the input digital signals into analog signals and input them to the quadrature modulator 4. The quadrature modulator 4 orthogonally modulates the baseband signals I and Q, which are converted into analog signals, and outputs the quadrature modulator 4. The output of the quadrature modulator 4 is high power amplified by the high power amplifier (HPA) 5. .

The value calculated by the distortion compensation calculator 1 distorts and outputs the baseband signals I and Q in advance to compensate for the value to be distorted at the time of high power amplification using the value output from the compensation data table 7. The compensation data table 7 stores the compensation data prepared by using the result of pre-measurement of the nonlinear characteristics of the amplification of the high power amplifier 5 in advance. The output value of the signal to be output from the compensation data table 7 is determined by the power of the baseband signals I and Q calculated by the power calculator 6. That is, the power calculated by the power calculator 6 is output to the compensation data table 7. The compensation data table 7 refers to the table according to the powers of the baseband signals I and Q, reads out corresponding compensation data, and outputs the compensation data to the distortion compensation calculating section 1.

Accordingly, the distortion compensation calculator 1 adds the baseband signals I and Q before quadrature modulation in advance to invert the distortion of the inverse characteristic for canceling the nonlinear distortion generated by the high power amplifier 4. ) Therefore, the high power amplified modulation signal in the high power amplifier 5 does not include nonlinear distortion.

In the nonlinear distortion compensation method using the conventional predistortion method, the compensation data table is referred to according to the power of the baseband signal. Therefore, there is a problem in that the performance of the entire circuit tends to be degraded due to characteristics and deviations or temperature changes of the high power amplifier 5.

Therefore, in order to improve the predistortion method, a method of feeding back and processing an output value has emerged. A predistortion method using the feedback value will be described with reference to FIG. 8.

The output of the high power amplifier 5 is branched in the directional divider 8, and the branched output signal is orthogonal demodulated in the orthogonal demodulator 9 and then fed back to the compensation data calculating section 10. The compensation data calculator 10 multiplies the feedback information with data of an embedded compensation data table (same as 7 in FIG. 7) and outputs the correction value. Regardless of the variation of the characteristics of the high power amplifier 5 or the temperature change, the highly accurate compensation data is outputted to the distortion compensation calculator 1 to reduce the influence of the above-mentioned defects.

However, the circuit described above also generates and uses pseudo nonlinear distortion, and thus does not sufficiently solve the above drawback. In addition, when the circuit is configured as described above, a complicated digital operation is performed, thereby increasing the circuit size. As a result, the power consumption increases, so that the operation time of the transmitter using the battery is shortened.

SUMMARY OF THE INVENTION An object of the present invention is to provide a nonlinear distortion compensation circuit and a nonlinear distortion compensation method capable of accurately compensating for nonlinear distortion caused by high power amplification even when the characteristics of the high power amplifier change. .

Another object of the present invention is to provide a nonlinear distortion compensating circuit and a nonlinear distortion compensating method capable of compensating for nonlinear distortion caused by high power amplification without using a complicated and large-scale digital arithmetic circuit or pseudo distortion generating circuit.

Still another object of the present invention is to provide a nonlinear distortion compensation method and a nonlinear distortion compensation circuit which can reduce power consumption.

The present invention for achieving the above object is a nonlinear distortion compensation circuit for compensating for nonlinear distortion generated during nonlinear high power amplification by a transmitter for performing orthogonal modulation of a baseband signal and amplifying the nonlinear high power amplification. A distortion extractor for extracting a nonlinear distortion component, a phase adjuster for adjusting a phase of a carrier used to orthogonally demodulate the distortion component extracted from the distortion extractor to a baseband region, and a distortion component extracted from the distortion extractor An orthogonal demodulation unit for orthogonal demodulation into a baseband region using the phase-adjusted carrier, and a distortion overlapping unit for superposing a distortion component of an inverse phase of the distortion component of the baseband region output from the orthogonal demodulation unit to the baseband signal; It is provided with.

In addition, the distortion extraction unit;

An attenuator for attenuating the nonlinear high output amplified modulation signal by a nonlinear high output amplified portion, an ideal phase shifter for shifting the phase of the modulated signal before nonlinear high output amplification, and a modulated signal shifted in phase with the attenuator from the output signal of the attenuator Subtractor to subtract,

The distortion overlapping portion;

An amplitude adjuster for amplitude adjustment of the amplitude level of the distortion component of the baseband region output from the orthogonal demodulator, and a subtractor for subtracting the distortion component of the baseband region amplitude adjusted by the amplitude adjuster from the baseband signal. .

The carrier used for quadrature demodulation of the distortion component extracted from the distortion extractor may be generated separately from a carrier used for quadrature modulation of the baseband signal.

The present invention for achieving the above object is a nonlinear distortion compensation method for compensating for the nonlinear distortion generated when the nonlinear high power amplification by a transmitter for orthogonal modulation of the baseband signal and the nonlinear high power amplification, the nonlinear high power amplified modulation signal Extracting a nonlinear distortion component from the baseband, adjusting a phase of a carrier used to orthogonally demodulate the extracted distortion component to a baseband region, and performing a baseband using the carrier whose phase adjustment is performed on the extracted distortion component. Orthogonal demodulation into a region, and superposing a distortion component of an inverse phase of the distortion component of the baseband region generated by the orthogonal demodulation onto the baseband signal.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a circuit diagram showing the configuration of a nonlinear distortion compensation circuit according to a first embodiment of the present invention. Next, the configuration and operation of the circuit according to the first embodiment of the present invention will be described in detail with reference to FIG. 1.

1 shows an orthogonal modulator 11, a directional coupler or divider 12, a high power amplifier (HPA) 13, a directional coupler or divider 14, an attenuator 15, a subtractor 16, a delay circuit or an ideal phase. 17, an orthogonal demodulation unit 18, a phase adjuster 19, a carrier generator 20, two amplitude adjusters (21, 22), subtractors (23, 24). In addition, the orthogonal modulator 11 is composed of a π / 2 phase shifter 111, multipliers 112 and 113, and an adder 114, and the orthogonal demodulation section 18 is a π / 2 phase shifter 181, multipliers ( 182, 183).

Attenuator 15, delay circuit or idealizer 17, subtractor 16, quadrature demodulator 18, phase adjuster 19, amplitude adjusters 21, 22, subtractors 23, 24 ) Constitutes the nonlinear distortion compensation circuit of the present invention.

Next, the operation of the present embodiment will be described. Each baseband signals I and Q are input to subtractors 23 and 24, respectively. Then, the signal is subtracted with the signal for distortion compensation described later and input to the quadrature modulator 11. In addition, the quadrature modulator 11 receives a signal generated from the carrier generator 20.

Next, the process of processing the baseband signal by the quadrature modulator 11 will be described. The baseband signal Q subtracted with the signal for distortion compensation described later is input to the multiplier 112 of the quadrature modulator 11. The other signal input to the multiplier 112 is a carrier outputted from the carrier generator 20 and having a π / 2 phase shift from the π / 2 phase 111. The baseband signal Q subtracted with the phase shifted carrier signal and the distortion compensation signal is multiplied by the multiplier 112 and input to the adder 114. In addition, the baseband signal I subtracted together with the signal for distortion compensation described later is input to another multiplier 113 of the quadrature modulator 11. Another signal input to the multiplier 113 is a carrier generated by the carrier generator 20. The multiplier 113 multiplies the two input signals and outputs the multiplied signal to the adder 114. Therefore, the adder 114 adds and outputs the output signal of the multiplier 112 and the output signal of the multiplier 113. Through this process, the baseband signals I and Q are orthogonally modulated. The orthogonally modulated signal is input to a directional coupler or divider 12. The directional coupler or divider 12 then distributes the signal at a predetermined rate and outputs it to the high power amplifier 13 and the delay circuit or phaser 17.

The high power amplifier 13 nonlinear high power amplification (gain K) and outputs the quadrature modulated signal to the directional coupler or divider 14. The directional coupler or divider 14 then branches the input signal at a predetermined rate and outputs it to the attenuator 15 and the output stage. The attenuator 15 attenuates the signal amplified by the high power amplifier 13 at a predetermined ratio (1 / K) and outputs it to the subtractor 16. The subtractor 16 extracts only the nonlinear amplified distortion component by subtracting the signal including the nonlinear distortion output from the high power amplifier 13 and the distortionless orthogonal modulated signal branched from the directional coupler or divider 12.

The nonlinear amplification distortion component is bifurcated into two multipliers 182 and 183 of the quadrature demodulator 18, respectively. Each of the multipliers 182 and 183 receives a signal for multiplying the input nonlinear amplification distortion component. The other signal j input to the multiplier 182 is a carrier signal generated by the carrier generator 20 and phase adjusted by the phase adjuster 19. The signal j phase-adjusted by the phase adjuster 19 is phase-shifted by π / 2 in the π / 2 idealizer 181 and input to the multiplier 183. The two multipliers 182 and 183 multiply the input signals to quadrature demodulate.                     

A signal h multiplied by the multiplier 182 and a signal I multiplied and demodulated by another multiplier 183 become a baseband signal, and the signals of each baseband are input to amplitude adjusters 21 and 22, respectively. do. The amplitude adjuster 21 amplitude-adjusts the input signal and outputs it to the subtractor 23 to which the baseband I signal is input. The other amplitude adjuster 22 amplitude-adjusts the input signal to input the baseband Q signal. To the subtractor 24.

Therefore, the subtractor 23 subtracts the signal of the distortion component which is likely to occur in the high power amplifier 13 from the input baseband signal I in advance. Accordingly, the subtractor 23 outputs the baseband signal I, in which the inverse distortion component is superimposed, to the quadrature modulator 11. The subtractor 24 subtracts the signal of the distortion component likely to occur in the high power amplifier 13 from the input baseband signal Q in advance. Therefore, the subtractor 24 outputs the baseband signal Q having the inverse distortion component overlapped to the quadrature modulator 11.

That is, the two subtractors 23 and 24 distort the inverse distortion characteristic (the characteristic of canceling the nonlinear distortion component generated at the time of high power amplification) in the baseband region generated by orthogonal demodulation of the distortion component extracted by the subtractor 16. It can be said that a component is superimposed on the baseband signal. Therefore, after the baseband signal in which the inverse distortion component is superimposed is orthogonally modulated by the orthogonal modulator 11, nonlinear distortion generated when the nonlinear high power amplification is performed in the high power amplifier 13 can be removed.

Next, the principle of the nonlinear distortion compensation described above will be described in detail.

Before describing the principle according to the configuration shown in FIG. 1, the configuration in which the position of the phase adjuster 19 is connected to the output terminal of the subtractor 16 will be described. That is, it demonstrates with the structure which has a phase adjuster between the subtractor 16 and the orthogonal demodulation part 18. FIG.

The distortion component g extracted by the subtractor 16 is phase adjusted by the phase adjuster and demodulated by the orthogonal demodulator 18. In this case, the nonlinear distortion component extracted by the subtractor 16 is expressed as Equation 1 below.

^{Ae j (φ + α)}

In Equation 1, A is an amplitude, φ is a phase when distortion is completely compensated for, and α is a phase deviation to be adjusted.

The phase adjuster multiplies e ^-jα to shift the phase by α [rad] in the signal output from the subtractor 16. In this way, the result of the process performed in the phase adjuster is expressed by Equation 2 below.

^{A · e j (φ + α} ) · e -jα = A · e jφ

And it is assumed that the signal output from the carrier generator 20 is cos θ of amplitude 1. Since there is no phase adjuster 19, the carriers input to the multipliers 182 and 183 are cosθ and sinθ. Therefore, when orthogonal demodulation of Equation 1 is performed using the signals, output signals of the multiplier 182 and the multiplier 183 are represented by Equation 3 and Equation 4, respectively.                     

^Ae jφcosθ

^Ae jφsinθ

Next, the nonlinear distortion compensation in the configuration of the present embodiment shown in FIG. 1 will be described with reference to the above description. In FIG. 1, the distortion component in g point is the same as that of <Equation 1>. The signal shown in Equation 1 is input to the orthogonal demodulator 18. In addition, it is assumed that the signal output from the carrier generator 20 is cosθ having an amplitude of 1. The phase adjuster 19 also multiplies e- ^jα . Since the π / 2 phase shifter 181 outputs a signal shifted in phase by j, the signal of j is output as shown in Equation 5 below, and the signal of k is represented by Equation 6 below. Is output together.

e ^-jαcosθ

e ^-jαsinθ

The g signals are orthogonal demodulated by Equations 5 and 6, and the orthogonal demodulated h and I signals are represented by Equations 7 and 8, respectively.                     

^{A · e j (φ + α} ) · e -jα · cosθ = A · e jφ · cosφ

^{A · e j (φ + α} ) · e -jα · sinθ = A · e jφ · sinφ

Equations 7 and 6 may be identical to Equations 3 and 4 described above. That is, since the signal after orthogonal demodulation becomes the same as the phase before orthogonal demodulation, it can be seen that equivalent phase adjustment can be performed.

2 is a flowchart illustrating a processing procedure according to an embodiment of the distortion compensation method of the present invention. Hereinafter, a processing sequence in which distortion is compensated according to the present invention will be described with reference to FIG. 2.

First, a nonlinear distortion component is extracted from a nonlinear high power amplified modulated signal in step 201. The carrier used for orthogonal demodulation of the distortion component extracted in step 202 is adjusted for phase. Thereafter, the distortion components extracted in step 203 are orthogonal demodulated and converted into baseband distortion components. In step 204, the distortion component of the inverse distortion characteristic in the baseband region, that is, the characteristic of canceling the nonlinear distortion generated at the time of nonlinear high output amplification, is subtracted from the baseband signal.

FIG. 3 is a characteristic diagram showing an operation confirmation result by calculator simulation of the circuit shown in FIG. Fig. 3A shows the waveform of the output signal of the high power amplifier 13 when the nonlinear distortion compensation circuit of the present invention is turned off. Fig. 3B shows the waveform of the output signal of the high power amplifier 13 when the nonlinear distortion compensation circuit of the present invention is turned on. When distortion compensation is performed by the nonlinear distortion compensation circuit, an effect of 14 to 16 dB can be obtained as an improvement rate of the adjacent channel power ratio (ACPR).

4 is a diagram showing a characteristic curve of output power according to ACPR versus input level characteristics. The present invention will now be described with reference to FIG. Referring to the ACPR vs. input level characteristics shown in FIG. 4, when the nonlinear distortion compensation circuit is turned on, if the phase or amplitude is adjusted to the optimum value in the maximum output state, the ACPR is not lowered at the output level lower than that. Do not. Therefore, operation control such as an adaptation circuit is not necessary, and thereafter, there is an effect that can be used without adjustment.

According to the present exemplary embodiment, the distortion generated in the high power amplifier 13 is converted into the distortion of the baseband region and then fed back to the baseband signal. This makes it possible to compensate for nonlinear distortion caused by high power amplification without using complicated and large-scale digital computing circuits or pseudo-distortion generation circuits. In addition, since the circuit size is smaller, the power consumption can be reduced. Therefore, when the orthogonal modulation circuit of the present embodiment is used in a transmitter such as a mobile phone using a battery as a power source, the operation time is long.

In addition, the present embodiment adopts a configuration in which the phase adjuster 19 adjusts the phase of the carrier of the orthogonal demodulator 18. The phase adjuster 19 only needs to adjust the phase of the carrier signal of a single frequency. Therefore, a phase adjuster can be simply configured using a variable capacitor and an inductor (or a variable inductor) as shown in FIGS. 5A to 5F as well as commercially available abnormalities. Therefore, the circuit size can be made smaller and can be configured inexpensively.

6 is a circuit diagram illustrating a configuration of a nonlinear distortion compensation circuit according to a second embodiment of the present invention. In the present embodiment, a carrier generator 25 for a carrier for orthogonal demodulation is provided separately from the carrier generator 20 for generating a carrier signal required for orthogonal modulation in the orthogonal modulator 11. The phase adjuster 19 adjusts the phase of the output signal of the carrier generator 25. As a result, the same effects and effects as those of the embodiment shown in FIG. 1 are obtained.

The present invention described above is not limited to the above-described embodiments, and may be implemented by various forms having different specific configurations, functions, actions, and effects within a range not departing from the gist of the present invention. In addition, a phase adjuster for adjusting the phase of the carrier for orthogonal demodulation of the distortion can be configured simply and inexpensively.

As described above, since the present invention feeds back the actually generated distortion, it is possible to more accurately compensate for the nonlinear distortion caused by the high power amplification. It is also complex and can compensate for nonlinear distortion due to high power amplification without the use of large digital computing circuits or pseudo distortion generators. In addition, power consumption can be reduced, and the phase adjuster for adjusting the phase of the carrier for quadrature demodulation can be made simple and inexpensive.

Claims (6)

A nonlinear distortion compensation circuit for compensating for nonlinear distortion generated during nonlinear high power amplification by a transmitter for performing quadrature modulation of a baseband signal and then performing nonlinear high power amplification. A distortion extraction unit for extracting a nonlinear distortion component from the nonlinear high output amplified modulation signal; A phase adjuster for adjusting a phase of a carrier used to orthogonally demodulate the distortion component extracted from the distortion extractor to a baseband region; An orthogonal demodulation unit which orthogonally demodulates the distortion component extracted from the distortion extraction unit into a baseband region by using the phase-adjusted carrier; And a distortion overlapping portion for superposing a distortion component of an inverse phase of the distortion component of the baseband region output from the orthogonal demodulation unit onto the baseband signal. The distortion extractor of claim 1, An attenuator for attenuating the nonlinear high power amplified modulation signal by the nonlinear high power amplified portion; An ideal phase shifter for shifting the phase of a modulated signal before nonlinear high power amplification; And a subtractor for subtracting a modulated signal shifted in phase by the phase shifter from the output signal of the attenuator. The distortion overlapping portion of claim 1 or 2, An amplitude adjuster for amplitude-adjusting the amplitude level of the distortion component of the baseband region output from the orthogonal demodulator; And a subtractor for subtracting the distortion component of the baseband region amplitude adjusted by the amplitude adjuster from the baseband signal. The method according to claim 1 or 2, And generating the carrier used for orthogonal demodulation of the distortion component extracted from the distortion extractor separately from the carrier used for orthogonal modulating the baseband signal. In the non-linear distortion compensation method for compensating for the non-linear distortion generated when the non-linear high-power amplification to a transmitter for orthogonal modulation of the baseband signal, the non-linear high power amplification, Extracting a nonlinear distortion component from the nonlinear high power amplified modulated signal; Adjusting a phase of a carrier used to orthogonally demodulate the extracted distortion component to a baseband region; Orthogonal demodulating the extracted distortion component into a baseband region using the carrier whose phase is adjusted; And superposing a distortion component of an inverse phase of the distortion component of the baseband region generated by the orthogonal demodulation on the baseband signal. The method of claim 3, And generating the carrier used for orthogonal demodulation of the distortion component extracted from the distortion extractor separately from the carrier used for orthogonal modulating the baseband signal.

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