JP2012175401A - Nonlinear compensation apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a nonlinear distortion compensator having a compensation performance which is excellent even for a portion of a low occurrence frequency.SOLUTION: A low frequency data handling unit 240 is provided in a compensation coefficient generation circuit 200. The low frequency data handling unit 240 comprises a data storage section 241, an occurrence count calculation section 242, an occurrence frequency determination section 243 and a low frequency data extraction section 244. The data storage section 241 successively stores therein polar coordinate data (r, θ) corresponding to original Iand Qsignals and polar coordinate data (r, θ) corresponding to fed-back Iand Qsignals. The occurrence count calculation section 242 calculates, for each amplitude value, how many times that amplitude value occurs. The occurrence frequency determination section 243 divides the number of times of occurrence into low frequency and high frequency. The low frequency data extraction section 244 extracts from the data storage section 241 data corresponding to the amplitude value determined as low frequency. For the low frequency data thus extracted, a compensation coefficient is calculated by a compensation coefficient calculation unit 230.

Description

  The present invention relates to a nonlinear compensation device for compensating for nonlinear distortion generated in a power amplifier used in a television transmitter or the like.

  A television transmitter is generally equipped with a device that compensates for nonlinear distortion of a power amplifier. In recent years, since digital television broadcasting has started, television transmitters are required to amplify digitally modulated signals. At this time, in order to secure a broadcast area, higher linearity is required than before.

In order to meet such a demand, for example, Patent Document 1 (Japanese Patent Laid-Open No. 2001-168774) discloses an OFDM transmission device including a nonlinear compensator. In Patent Document 1, an error comparison between the original signal and a signal including distortion fed back from the output of the power amplifier is performed by digital signal processing. Then, an amplitude error and a phase error with respect to the input / output characteristics are calculated.
Here, a compensation amount table is provided in advance, and several patterns of distortion compensation amounts are set at the time of initial setting. Based on the calculated error, a distortion compensation amount for compensating the error is read from a compensation amount table. The read distortion compensation amount is added to the original signal. Thus, predistortion for canceling the nonlinear distortion of the power amplifier is performed.

JP 2001-168774 A

  In the conventional method, it is considered that the distortion characteristics with high occurrence frequency can be compensated with high accuracy and good followability. However, for distortion characteristics with low occurrence frequency such as whether or not there is only once in a single calculation period, there is not enough data to calculate the amount of distortion compensation, and compensation accuracy is lower than characteristics with high occurrence frequency. turn into.

For example, a case where an OFDM (Orthogonal Frequency Division Multiplexing) modulation signal is amplified by a power amplifier is taken as an example.
At this time, the power amplifier has good linearity with respect to a small amplitude component often used as a power amplifier. However, it is general that nonlinearity appears with respect to a large amplitude component. is there.
Here, a multiplexed modulation wave such as OFDM modulation has a feature that the frequency of signal generation decreases as the distance from the average power increases. Therefore, in this case, the characteristics of the high amplitude region where distortion is to be compensated cannot be obtained sufficiently, and satisfactory compensation performance may not be obtained.

  An object of the present invention is to provide a non-linear distortion compensator capable of improving the compensation performance for a portion with low occurrence frequency in distortion compensation of a power amplifier.

The nonlinear compensator of the present invention is
A distortion compensator for removing distortion generated in an electronic circuit including the amplifier by performing predistortion processing on an input signal of the amplifier;
A compensation coefficient calculation unit that calculates a compensation coefficient used for the predistortion processing based on the feedback signal obtained by feeding back the input signal and the output signal output from the amplifier;
A data storage unit for storing the input signal and the feedback signal;
A low-frequency data extraction unit that extracts data with low occurrence frequency from the data stored in the data storage unit,
The compensation coefficient calculation unit calculates the compensation coefficient for the low frequency data extracted by the low frequency data extraction unit.

1 is a block diagram showing a configuration of a first embodiment. 2 is a diagram showing a configuration of a compensation coefficient generation circuit 200. FIG. The figure which illustrated the generating frequency and generating frequency for every amplitude value.

Embodiments of the present invention will be illustrated and described with reference to reference numerals attached to respective elements in the drawings.
(First embodiment)
FIG. 1 is a block diagram showing the configuration of the first embodiment.
As a first embodiment of the present invention, a digital television transmitter 100 including a nonlinear compensator is shown.
The digital television transmitter 100 has a feed forward path and a feedback path.
The feedforward path includes a modulator 111, a nonlinear distortion compensator 112, a quadrature modulator 113, a frequency UP conversion unit 114, a power amplifier 115, and a directional coupler 116.
The feedback path includes a frequency DOWN conversion unit 121, an orthogonal demodulator 122, and a compensation coefficient generation circuit 200.

First, the feedforward path will be described.
The modulator 111 outputs an I ₁ signal and a Q ₁ signal that are orthogonal to each other. The I ₁ signal and the Q ₁ signal are input to the nonlinear distortion compensator 112 and subjected to predistortion processing by the nonlinear distortion compensator 112.
Here, the predistortion process is executed by the compensation coefficient provided from the compensation coefficient generation circuit 200, and a method for calculating the compensation coefficient will be described later with reference to FIG.

The predistorted I ₁ signal and Q ₁ signal are subjected to quadrature modulation by the quadrature modulator 113 and frequency conversion by the frequency UP conversion unit 114 to be converted into an RF signal, and then input to the power amplifier 115. The RF signal is amplified by the power amplifier 115 and output.

Next, the feedback path will be described.
A directional coupler 116 is provided following the power amplifier 115, and an output signal from the power amplifier 115 is sampled by the directional coupler 116. The sampled signal is frequency converted by the frequency DOWN conversion unit 121 and converted into a baseband signal. Further, the baseband signal is decomposed into an I ₂ signal and a Q ₂ signal by the quadrature demodulator 122.

Here, if the signal from the power amplifier 115 includes nonlinear distortion, the distortion is also included in the I ₂ signal and Q ₂ signal output from the quadrature demodulator 122 as they are.

In the feedback path, a compensation coefficient generation circuit 200 is disposed between the modulator 111 and the quadrature demodulator 122.
The compensation coefficient generation circuit 200 receives the I ₂ signal and Q ₂ signal output from the quadrature demodulator 122. Further, the original I ₁ signal and Q ₁ signal output from the modulator 111 are input to the compensation coefficient generation circuit 200.

The original I ₁ signal and Q ₁ signal and the I ₂ signal and Q ₂ signal fed back from the power amplifier 115 are input to the compensation coefficient generation circuit 200, and the compensation coefficient generation circuit 200 compensates for distortion for predistortion. A coefficient is generated. The generated distortion compensation coefficient is output to the nonlinear distortion compensator 112.

FIG. 2 is a diagram showing a configuration of the compensation coefficient generation circuit 200. As shown in FIG.
The original I ₁ signal and Q ₁ signal are input to the coordinate conversion unit 211 via the RAM.
Similarly, the fed back I ₂ signal and Q ₂ signal are input to the coordinate conversion unit 212 via the RAM.
The coordinate conversion units 211 and 212 both convert the orthogonal coordinate system (I, Q) to the polar coordinate system (r, θ).

Both the data converted into the polar coordinate format by the coordinate conversion units 211 and 212 are branched after being output from the coordinate conversion units 211 and 212 and input to the error calculation unit 220.
The error calculation unit 220 includes an error vector extraction unit 221, an in-phase error calculation unit 222, and a quadrature error calculation unit 223.
The error vector extraction unit 221 includes polar coordinate data (r ₁ , θ ₁ ) corresponding to the original I ₁ signal and Q ₁ signal and polar coordinate data (r ₂ , θ corresponding to the fed back I ₂ signal and Q ₂ signal. ₂ ) and, after synchronizing, extract the error vector by relative comparison.
An amplitude error ΔR is obtained from the error vector by the in-phase error calculation unit 222, a phase error ΔΘ is obtained by the quadrature error calculation unit 223, and a compensation coefficient is calculated by the compensation coefficient calculation unit 230 from these error values.

Here, the compensation coefficient generation circuit 200 is further provided with a low frequency data correspondence unit 240. The low frequency data correspondence unit 240 includes a data storage unit 241, an occurrence count calculation unit 242, an occurrence frequency determination unit 243, A low-frequency data extraction unit 244.
Both the data converted into the polar coordinate format by the coordinate conversion units 211 and 212 are output from the coordinate conversion units 211 and 212, and then input to the data storage unit 241 and stored.
The data storage unit 241 stores polar coordinate data (r ₁ , θ ₁ ) corresponding to the original I ₁ signal and Q ₁ signal and polar coordinate data (r ₂ , θ ₂ ) corresponding to the fed back I ₂ signal and Q ₂ signal. Are accumulated, the occurrence number calculation unit 242 calculates the number of occurrences of the amplitude value for each amplitude value with respect to the original signal (r ₁ , θ ₁ ).

For example, as shown in FIG. 3, the occurrence count calculation unit 242 extracts all data of a specific amplitude value from the original signal (r ₁ , θ ₁ ) stored in the data storage unit 241, and the amplitude value is Ask how many times it has occurred.
The counting period may be the number of times the data of the amplitude value has occurred in the past few seconds for the past few seconds, or may be a longer period depending on the capacity of the data storage unit 241. .

The calculated occurrence frequency is output to the occurrence frequency determination unit 243. The occurrence frequency determination unit 243 divides the occurrence frequency into a low frequency and a high frequency.
This is assumed to be a low frequency when a predetermined threshold value set in advance is used and the number of occurrences is less than or equal to the predetermined threshold value.

  As an example, the occurrence frequency that is not once in 1_OFDM symbol time is determined to be low. However, since 1_OFDM symbol time differs depending on the modulation method (DVB, ISDB, etc.), the threshold is It is set appropriately depending on the system (including analog modulation) and the required device performance.

The occurrence frequency determination unit 243 provides the low frequency data extraction unit 244 with information on the amplitude value determined as low frequency.
The low-frequency data extraction unit 244 receives the original data (r ₁ , θ ₁ ) and feedback data (r ₂ , θ ₂ ) corresponding to the amplitude value for the amplitude data determined to be low frequency, as a data storage unit. Extract from 241.
For example, if the amplitude value R ₃ is determined to be low frequency, along with the original data (r _1, θ ₁₎ amplitude value of R ₃ is extracted from the data storage unit 241, the amplitude value of R ₃ Feedback data (r ₂ , θ ₂ ) paired with certain original data (r ₁ , θ ₁ ) is extracted from the data storage unit 241.
The data extracted in this way is output to the error calculator 220.

  The compensation coefficient is calculated for the low-frequency data extracted in this way as described above. That is, after synchronizing both data, an amplitude error ΔR and a phase error ΔΘ are obtained by relative comparison, and a compensation coefficient is calculated by the compensation coefficient calculation unit 230 from these error values.

The compensation coefficient obtained in this way is provided from the compensation coefficient generation circuit 200 to the nonlinear distortion compensator 112. Using this compensation coefficient, predistortion processing is performed on the I ₁ signal and the Q ₁ signal. As a result, the signal output from the power amplifier is a signal whose distortion is compensated.

  Here, the nonlinear distortion compensator 112 and the compensation coefficient generation circuit 200 constitute a nonlinear compensator.

According to such a first embodiment, the following effects are obtained.
Data is stored in the data storage unit 241, and a compensation coefficient is generated from the stored data for a signal portion having a low occurrence frequency.
As a result, the compensation accuracy can be dramatically improved even for a part having a low occurrence frequency.
Previously, sufficient compensation could not be provided for samples that occurred less frequently in the sampling period for creating the compensation coefficient, or that did not occur once in the sampling period. .
In this regard, according to the present embodiment, it is possible to improve the accuracy even for a portion having a low occurrence frequency by using the accumulated data.

Instead of calculating all the compensation coefficients using the accumulated data here, the conventional coefficient calculation method is used for the frequently occurring characteristics.
This is because if the coefficient is calculated using only the accumulated data, the followability with respect to a steep characteristic change (deterioration) is lowered.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 100 ... Digital television transmitter, 111 ... Modulator, 112 ... Nonlinear distortion compensator, 113 ... Quadrature modulator, 114 ... Frequency UP conversion part, 115 ... Power amplifier, 116 ... Directional coupler, 121 ... Frequency DOWN conversion part , 122 ... quadrature demodulator, 200 ... compensation coefficient generation circuit, 211 ... coordinate converter, 212 ... coordinate converter, 220 ... error calculator, 221 ... error vector extractor, 222 ... in-phase error calculator, 223 ... quadrature error Calculation unit, 230 ... compensation coefficient calculation unit, 240 ... low frequency data corresponding unit, 241 ... data storage unit, 242 ... occurrence frequency calculation unit, 243 ... occurrence frequency determination unit, 244 ... low frequency data extraction unit.

Claims (5)

A distortion compensator for removing distortion generated in an electronic circuit including the amplifier by performing predistortion processing on an input signal of the amplifier;
A compensation coefficient calculation unit that calculates a compensation coefficient used for the predistortion processing based on the feedback signal obtained by feeding back the input signal and the output signal output from the amplifier;
A data storage unit for storing the input signal and the feedback signal;
A low-frequency data extraction unit that extracts data with low occurrence frequency from the data stored in the data storage unit,
The non-linear compensation device, wherein the compensation coefficient calculation unit calculates the compensation coefficient for the low frequency data extracted by the low frequency data extraction unit. In the nonlinear compensation device according to claim 1,
In addition to calculating the compensation coefficient by sequentially processing the input signal and the feedback signal in the order of input, the compensation coefficient calculation unit further adds the low frequency data extracted by the low frequency data extraction unit. A non-linear compensator, wherein the compensation coefficient is calculated. In the nonlinear compensation device according to claim 1 or claim 2,
The non-linear compensation device, wherein the frequency of data generation is determined based on the number of occurrences of each amplitude value obtained by counting the number of occurrences for each amplitude value of the signal.   4. A television transmitter comprising the nonlinear compensation device according to claim 1. Accumulating an input signal and a feedback signal obtained by feeding back an output signal obtained by amplifying the input signal with an amplifier;
Extract data with low frequency of occurrence from the accumulated data,
Calculate a compensation coefficient to be used for predistortion processing based on the extracted data,
A non-linear compensation method, wherein predistortion processing is performed on the input signal of the amplifier using the compensation coefficient.

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