JP2006303787A - Transmitter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmitter for executing calibration for its transmission signal while reducing distortion in the transmission signal. <P>SOLUTION: A first RF section 14 generates the transmission signal by applying frequency conversion to an input signal and amplifying the converted signal and then outputs the generated transmission signal. A second RF section 24 feed-backs the transmission signal and applies frequency conversion to the fed-back transmission signal to produce a feedback signal. A distortion compensation section 12 introduces a distortion compensation coefficient for the first RF section 14 on the basis of the feedback signal and uses the introduced distortion compensation coefficient to compensate the input signal. A pilot signal generating section 20 and an adder section 22 superimpose a pilot signal on the transmission signal at the pre-stage of the frequency conversion and a feedback correction section 26 corrects an error caused by the frequency conversion at the post-stage of the frequency conversion on the basis of the superimposed pilot signal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a transmission technique, and more particularly to a transmission apparatus that transmits a signal while compensating for distortion components.

  As a radio base station of a radio communication system, an adaptive array radio base station using an array antenna has been put into practical use. In order to execute transmission / reception with appropriate antenna directivity between the adaptive array radio base station and a desired user terminal, the adaptive array radio base station has an accurate weighting factor for each antenna element constituting the array antenna. Derivation is required. In general, a receiving device of an adaptive array radio base station compares a known signal included in a received signal from a predetermined user terminal with a known signal stored therein, and derives a weighting factor so as to reduce the error. To do. Further, the receiving apparatus executes the receiving process while using such weighting factors. As a result, the S / N or S / I in the received signal from the predetermined user terminal is improved. Here, S indicates signal power, N indicates noise power, and I indicates interference wave power. In this way, signals from a predetermined user terminal are received by a plurality of antennas, weighted and then added, so that the adaptive array radio base station secures an improved S / N or S / I it can. Therefore, the transfer characteristic of the circuit after being received by the antenna and the spatial propagation characteristic before being received by the antenna may be handled integrally.

  In a transmission apparatus in an adaptive array radio base station, weighting is applied to transmission signals to be output from a plurality of antennas so that S / N or S / I is improved according to the reception status of a user terminal. In this case, S / N or S / I should be evaluated according to the location of the user terminal. However, in general, in a transmission apparatus, a weighting factor for a received signal is also used for a transmission signal by utilizing reversibility of a propagation path between an adaptive array radio base station and a user terminal. Even if reversibility of the propagation path between the adaptive array radio base station and the user terminal is shown, a signal is transmitted irreversibly between the transmitter and the receiver inside the adaptive array radio base station. The individual deviation of the connected receiving device should be reflected in the transmitting device. For this reason, the transmission device and the reception device connected to each antenna require calibration called calibration.

  Further, when the frequency for transmission and the frequency for reception in the adaptive array radio base station are different, the reversibility of the propagation path is not established. In such a case, the adaptive array radio base station may estimate the direction of the user terminal from received signals received by a plurality of antennas, and transmit a signal in the estimated direction of the user terminal. Such transmission is also referred to as adaptive beamforming. In beam forming, since the user direction is estimated from the amplitude and phase information of the received signal at each antenna, the receiving apparatus connected to each antenna requires calibration.

  The transmission device outputs the transmission signal amplified by the amplification unit. In general, nonlinear distortion occurs in the amplification unit. On the other hand, in order to use in an urban area where a plurality of wireless communication systems can exist and to make effective use of frequencies, a transmission device is required to transmit a signal with good out-of-band frequency characteristics. In addition, the transmission device consumes a large amount of power. In order to save power, there is no choice but to use a transmission device in which the maximum power without distortion is as low as possible and an amplifying unit that is slightly distorted at peak power is used. Therefore, reduction of the influence of nonlinear distortion is required. In order to compensate for such non-linear distortion, the transmission apparatus preliminarily defines a distortion compensation coefficient corresponding to the non-linear distortion, and compensates the transmission signal before being amplified by the amplifying unit with the distortion compensation coefficient. Such processing is also called a predistortion method.

A transmission apparatus provided with a predistortion system has the following configuration. The predistortion unit performs distortion compensation on the baseband signal using a distortion compensation coefficient. The orthogonal modulation unit orthogonally modulates the distortion-compensated baseband signal, and the amplification unit amplifies the orthogonally modulated signal. Further, the amplified signal is transmitted from the antenna as a transmission signal. The orthogonal demodulation unit feeds back a part of the transmission signal and orthogonally demodulates the transmission signal. The coefficient updating unit derives an error signal by comparing the quadrature demodulated signal with the baseband signal input to the predistortion unit. Further, the coefficient updating unit derives a distortion compensation coefficient based on the error signal. The derived distortion compensation coefficient is used in the predistortion unit. That is, the transmission apparatus is configured by a closed loop including a predistortion unit, an orthogonal modulation unit, an amplification unit, an orthogonal demodulation unit, and a coefficient update unit (see, for example, Patent Document 1).
JP 2002-64411 A

  Under such circumstances, the present inventor has come to recognize the following problems. If the predistortion method is applied to the adaptive array radio base station, the out-of-band frequency characteristic in the adaptive array radio base station is improved. In addition, the transmission apparatus having the above-described predistortion is configured to compensate for distortion. At the same time, the amplitude and phase of the baseband signal are set so that the same amplitude characteristic and phase characteristic as the transmission signal are obtained. to correct. In the above-described closed loop, when the amplitude and phase characteristics of the quadrature demodulation unit are known or when the error of the amplitude and phase characteristics between the plurality of quadrature demodulation units is small, even if there are a plurality of predistortion units, The amplitude and phase of the transmission signal are the same. That is, calibration is not necessary. However, in general, the amplitude characteristics and phase characteristics of the quadrature demodulation units are not the same among the plurality of quadrature demodulation units, and change with time. Therefore, calibration is also required when applying the predistortion method.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a transmission apparatus that performs calibration on a transmission signal while reducing distortion of the transmission signal.

  In order to solve the above problems, a transmission apparatus according to an aspect of the present invention generates a transmission signal by amplifying a baseband input signal while performing frequency conversion, and then outputs the generated transmission signal. And a feedback unit that generates a baseband feedback signal by performing frequency conversion while feeding back a transmission signal output from the output unit, and a feedback signal generated by the feedback unit. A derivation unit that derives a distortion compensation coefficient, and a compensation unit that compensates an input signal in the output unit using the distortion compensation coefficient derived by the derivation unit. The feedback unit includes means for superimposing the pilot signal on the transmission signal before the frequency conversion, and means for correcting an error caused by the frequency conversion based on the superimposed pilot signal at the subsequent stage of the frequency conversion.

  According to this aspect, since the distortion compensation coefficient for the transmission signal is derived by feeding back the transmission signal, the distortion of the transmission signal can be reduced. Further, when the transmission signal is fed back, the pilot signal is superimposed, and an error that occurs during the feedback is corrected based on the pilot signal, so that the calibration for the transmission signal can be executed.

  The feedback unit may superimpose the pilot signal in a band close to the band of the transmission signal. In this case, calibration on the transmission signal can be executed while reducing the influence on the transmission signal.

  The feedback unit includes a means for performing separation from the frequency-converted transmission signal into a superimposed pilot signal component and the remaining transmission signal component, and an error caused by frequency conversion based on the separated pilot signal component. And means for correcting the components of the remaining transmission signal separated by the derived error. In this case, the component of the transmission signal can be corrected by the superimposed pilot signal.

  A plurality of output units may be provided to correspond to each of the plurality of antennas, and a plurality of feedback units, derivation units, and compensation units may be provided to correspond to each of the plurality of output units. In this case, calibration for a plurality of antennas can be performed.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  According to the present invention, it is possible to execute calibration for a transmission signal while reducing distortion of the transmission signal.

  Before describing the present invention in detail, an outline will be described. Embodiments described herein relate generally to a transmission apparatus that outputs a radio frequency signal from an antenna. Here, the transmission apparatus corresponds to a predetermined wireless communication system, and executes transmission processing according to the modulation method, error correction method, and wireless frequency specified in the wireless communication system. Further, the transmission device supports a predistortion method, and after performing distortion compensation on a baseband signal to be transmitted (hereinafter referred to as “input signal”), conversion to radio frequency and amplification (hereinafter referred to as radio frequency). And the amplified signal is referred to as “transmission signal”).

  Further, in order to execute the predistortion method, the transmission apparatus performs conversion to the baseband while feeding back the transmission signal (hereinafter, the signal converted to the baseband is referred to as “feedback signal”). Then, calibration is performed on the feedback signal. As a result, amplitude and phase errors in the feedback system are reduced. That is, the amplitude and phase in the feedback signal are close to the amplitude and phase in the transmission signal. The transmitter according to the present embodiment generates a feedback signal from a signal obtained by superimposing a pilot signal on a transmission signal in order to execute calibration. Further, the amplitude and phase errors in the feedback signal are corrected based on the pilot signal component included in the feedback signal and the pilot signal defined in advance.

  FIG. 1 shows a configuration of a transmission apparatus 100 according to an embodiment of the present invention. The transmission apparatus 100 includes a baseband processing unit 10, a distortion compensation unit 12, a first RF unit 14, an antenna 16, a directional coupler 18, a pilot signal generation unit 20, an addition unit 22, a second RF unit 24, and a feedback correction unit 26. The distortion detection unit 28 is included.

  The baseband processing unit 10 generates a baseband signal to be transmitted. Such a signal is called an “input signal” as described above. The baseband processing unit 10 executes error correction processing according to an error correction method specified in the wireless communication system, and executes mapping processing according to a modulation method specified in the wireless communication system. Since these are known techniques, the description thereof is omitted.

  The distortion compensator 12 performs predistortion distortion compensation processing on the input signal. As a result, the input signal has reverse distortion characteristics. Here, the distortion characteristic is a distortion characteristic in the first RF unit 14 to be described later, and particularly a distortion characteristic in an amplifying unit (not shown) included in the first RF unit 14. In order to execute the above processing, the distortion compensation unit 12 stores a distortion compensation table in which reverse distortion characteristics are described so as to cancel nonlinear distortion generated in an amplification unit (not shown). The distortion compensation unit 12 derives a distortion compensation coefficient for the first RF unit 14 from the distortion compensation table in accordance with the distortion amount derived by the distortion detection unit 28 described later. Furthermore, the distortion detection unit 28 performs distortion compensation on the input signal using a distortion compensation coefficient. Here, details of the distortion compensation table and distortion compensation will not be described, but a known technique relating to a predistortion method may be used.

  The first RF unit 14 generates a transmission signal by amplifying the input signal while performing frequency conversion. Here, the frequency conversion includes orthogonal modulation and frequency conversion to a radio frequency. Note that the frequency conversion may be performed a plurality of times while using the intermediate frequency. The first RF unit 14 includes an amplifying unit (not shown) as described above. Further, the first RF unit 14 outputs the generated transmission signal from the antenna 16. It is assumed that the transmission signal is transmitted to a receiving device (not shown).

  The directional coupler 18 extracts part of the transmission signal output from the first RF unit 14. The pilot signal generation unit 20 generates a pilot signal, and converts the frequency into a frequency band of the transmission signal, that is, a radio frequency (hereinafter, the frequency-converted pilot signal is also referred to as a “pilot signal”). At that time, the pilot signal generation unit 20 converts the frequency of the pilot signal to a band close to the band of the transmission signal. If a quadrature modulator is used for frequency conversion in pilot signal generation unit 20, conversion to a frequency obtained by adding or subtracting the pilot signal frequency to the carrier frequency of the pilot signal is performed. On the other hand, if a scalar modulator is used for frequency conversion in pilot signal generation unit 20, conversion to both the frequency obtained by adding the pilot signal frequency to the carrier frequency of the pilot signal and the subtracted frequency is performed. Here, if the pilot signal is inserted into the frequencies on both sides of the transmission signal, even if the transmission signal has a certain frequency band and there is a slope of the frequency characteristic, calibration by the pilot signals on both sides becomes possible. Therefore, the accuracy of calibration can be improved. Adder 22 superimposes the pilot signal on the transmission signal.

  The second RF unit 24 generates a feedback signal by frequency-converting the transmission signal output from the adder 22 and the pilot signal. Here, the frequency conversion includes quadrature detection and frequency conversion from a radio frequency. Note that the frequency conversion may be performed a plurality of times while using the intermediate frequency.

  The feedback correction unit 26 corrects an error caused by frequency conversion in the second RF unit 24 for the feedback signal based on the pilot signal superimposed by the addition unit 22. That is, the feedback correction unit 26 separates the feedback signal into the superimposed pilot signal component and the remaining transmission signal component. The feedback correction unit 26 derives an error caused by the frequency conversion based on the separated pilot signal component. More specifically, pilot signals are stored in a table in advance, and an error is derived by comparing the separated pilot signal components with the pilot signals stored in the table. Further, the feedback correction unit 26 corrects the components of the remaining separated transmission signal based on the derived error. At that time, correction is performed so as to reduce the error. When a plurality of pilot signals are inserted, the feedback correction unit 26 derives an error for each of the plurality of pilot signals, and interpolates the errors to respond to the frequency band of the transmission signal. May be derived. Further, the feedback correction unit 26 may derive a correction amount by executing statistical processing such as averaging for a plurality of errors.

  The distortion detection unit 28 compares the signal output from the feedback correction unit 26 with the input signal output from the baseband processing unit 10 and outputs an error signal. The signal output from the feedback correction unit 26 does not include a pilot signal component. The error signal corresponds to the amount of distortion. For the above processing, a known predistortion method may be used. The distortion detector 28 outputs the distortion amount to the distortion compensator 12. With the above configuration, the distortion compensation unit 12, the first RF unit 14, the directional coupler 18, the addition unit 22, the second RF unit 24, the feedback correction unit 26, and the distortion detection unit 28 constitute a closed loop. The calibration of the second RF unit 24 in the closed loop is performed by the pilot signal generation unit 20, the addition unit 22, and the feedback correction unit 26.

  In this configuration, the baseband processing unit 10, the distortion compensation unit 12, the feedback correction unit 26, and the distortion detection unit 28 can be realized in hardware by a CPU, memory, or other LSI of an arbitrary computer. In terms of software, it is realized by a program having a communication function loaded in a memory, but here, functional blocks realized by their cooperation are depicted. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms by hardware only, software only, or a combination thereof.

  FIG. 2 shows a configuration of the pilot signal generation unit 20. The pilot signal generation unit 20 includes a local signal oscillation unit 40, a pilot signal oscillation unit 42, a quadrature component multiplication unit 44, an in-phase component multiplication unit 46, a phase shift unit 48, and an addition unit 50. The configuration in FIG. 2 corresponds to the configuration of the pilot signal generation unit 20 using quadrature modulation.

  The local signal oscillator 40 oscillates a local signal having a frequency near the radio frequency. The pilot signal oscillating unit 42 oscillates a pilot signal defined in advance. The phase shifter 48 shifts the phase by π / 2. The quadrature component multiplier 44 and the in-phase component multiplier 46 perform quadrature modulation, and the adder 50 adds the quadrature modulation results and outputs the result.

FIGS. 3A to 3B show signals output from the adding unit 22. FIG. 3A shows the frequency f on the horizontal axis. FIG. 3A shows a case where the pilot signal is superimposed on a frequency lower than the frequency of the transmission signal. The frequency of the local signal oscillator 40 in FIG. 2 is indicated as “f _loc ”, and the frequency of the pilot signal oscillator 42 is indicated as “f _plt ”. On the other hand, FIG. 3B shows a case where the pilot signal is superimposed on a frequency higher than the frequency of the transmission signal.

  FIG. 4 shows another configuration of the pilot signal generation unit 20. The pilot signal generation unit 20 includes a local signal oscillation unit 40, a pilot signal oscillation unit 42, and a scalar modulation unit 60. The configuration in FIG. 4 corresponds to the configuration of the pilot signal generation unit 20 using scalar modulation.

  The local signal oscillator 40 and the pilot signal oscillator 42 are the same as those in FIG. The scalar modulator 60 performs modulation so that the pilot signal oscillated by the pilot signal oscillator 42 is arranged on both sides of the frequency of the local signal oscillated by the local signal oscillator 40.

FIG. 5 shows a signal output from the adding unit 22. FIG. 5 shows the frequency f on the horizontal axis in the same manner as in FIGS. In this case, the pilot signal is arranged on both sides of the frequency “f _loc ” of the local signal oscillating unit 40 at a frequency separated by the frequency “f _plt ” of the pilot signal oscillating unit 42. For example, if the frequency “f _loc ” of the local signal oscillating unit 40 is set to be the same as the frequency of the transmission signal, a pilot signal is formed at frequencies on both sides of the transmission signal. In this case, since the calibration is executed at the frequencies on both sides of the transmission signal, even if the second RF unit 24 in FIG. .

  The operation of the transmission apparatus 100 configured as above will be described. The baseband processing unit 10 outputs an input signal. The distortion compensation unit 12 derives a distortion compensation coefficient while referring to the distortion compensation table, and compensates the input signal using the distortion compensation coefficient. The first RF unit 14 performs frequency conversion and amplification on the compensated input signal to generate a radio frequency transmission signal. Further, the first RF unit 14 outputs a transmission signal from the antenna 16. The directional coupler 18 feeds back a part of the transmission signal. The adder 22 superimposes the pilot signal output from the pilot signal generator 20 on the transmitted transmission signal. The second RF unit 24 performs frequency conversion on the transmission signal and the pilot signal to generate a baseband feedback signal. The feedback correction unit 26 derives a pilot signal component of the feedback signal and a predetermined pilot signal error, and derives a correction amount from the error. The feedback correction unit 26 corrects components other than the pilot signal in the feedback signal based on the derived correction amount. The distortion detection unit 28 derives a distortion amount by comparing the input signal with the signal corrected by the feedback correction unit 26. The distortion compensation unit 12 derives a distortion compensation coefficient based on the distortion amount.

  FIG. 6 shows a configuration of a transmission apparatus 100 according to a modification example of the present invention. The transmission apparatus 100 includes a first transmission unit 70a, a second transmission unit 70b, a third transmission unit 70c, a fourth transmission unit 70d, which are collectively referred to as a transmission unit 70, and a first antenna 16a and a second antenna, which are collectively referred to as an antenna 16. 16b, a third antenna 16c, a fourth antenna 16d, and a pilot signal oscillator 72. Other configurations are the same as those in FIG.

  The transmitting apparatus 100 includes a plurality of antennas 16 as illustrated. In addition, a plurality of transmission units 70 are provided so as to correspond to each of the plurality of antennas 16. A plurality of transmission units 70 perform transmission diversity processing and adaptive array processing. Note that transmission diversity processing and adaptive array processing need only be performed based on known techniques, and thus description thereof is omitted. Further, antenna selection in transmission diversity processing and derivation of weighting factors in adaptive array signal processing are performed in cooperation with a receiving apparatus (not shown). Further, a communication device may be configured by combining a receiving device (not shown) integrally with the transmitting device 100.

  The transmission unit 70 has the same configuration as that of the transmission device 100 of FIG. That is, a plurality of first RF units 14 are provided so as to correspond to each of the plurality of antennas 16. A plurality of directional couplers 18, second RF units 24, feedback correction units 26, distortion detection units 28, and distortion compensation units 12 are provided so as to correspond to the plurality of first RF units 14 provided. . Here, only one pilot signal generation unit 20 is provided, and the plurality of transmission units 70 use one pilot signal generation unit 20. The pilot signal oscillating unit 72 oscillates a common pilot signal over the plurality of transmitting units 70.

  With the above configuration, when a plurality of predistortion methods are applied to adaptive array processing or the like, pilot signals to be input to the plurality of transmission units 70 can be shared. However, even with such a configuration, when a plurality of physically isolated distortion compensators 12 are used at the same time, a propagation delay of a connection cable or the like occurs when the pilot signal is demultiplexed. The propagation delay of the pilot signal can be made uniform by the calibration described above.

  The adder 22 superimposes the pilot signal on the feedback transmission signal, and the feedback correction unit 26 performs correction so as to make the amplitude and phase of the pilot signal constant. As a result, the amplitude and phase error caused by the second RF unit 24 are reduced. Further, by controlling so as to reduce the error in the above-described closed loop, the relationship between the amplitude and phase of the input signal output from the baseband processing unit 10 is also preserved at the antenna 16 end. For example, even when a plurality of distortion compensators 12 are provided, the amplitude and phase of the transmission signals coincide with each other in the vicinity of the end of the antenna 16.

  According to the embodiment of the present invention, even when the amplitude and phase errors are not the same between the plurality of second RF units and change with time, the distortion of the transmission signal is compensated while compensating for the distortion of the transmission signal. Calibration can be performed. Further, since the distortion compensation coefficient for the transmission signal is derived by feeding back the transmission signal, the distortion of the transmission signal can be reduced. Further, when the transmission signal is fed back, the pilot signal is superimposed, and an error that occurs during the feedback is corrected based on the pilot signal, so that the calibration for the transmission signal can be executed. In addition, since the pilot signal is superimposed on a frequency close to the frequency of the transmission signal, calibration on the transmission signal can be performed while reducing the influence on the transmission signal. In addition, since the pilot signal is superimposed on both sides of the frequency of the transmission signal, calibration can be executed while considering the influence of the transmission signal on the signal band. Further, by superimposing a plurality of pilot signals, it is possible to execute calibration in consideration of the bandwidth of the transmission signal. Further, even when a plurality of antennas are provided, calibration is performed on transmission signals corresponding to the respective antennas, so that calibration can be performed on the entire plurality of antennas. Further, by executing calibration, it is possible to improve data transmission characteristics. Further, by compensating the distortion component, the intensity of the signal component outside the band can be reduced.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to the combination of each component and each processing process, and such modifications are also within the scope of the present invention. .

  In the embodiment of the present invention, the pilot signal generation unit 20 generates a pilot signal so as to have a frequency close to the frequency of the transmission signal. However, the present invention is not limited to this. For example, the pilot signal generation unit 20 may generate a pilot signal so as to have the frequency of the transmission signal. At that time, a selection unit is provided instead of the addition unit 22, and the selection unit selects either the transmission signal or the pilot signal while time-sharing. Further, the feedback correction unit 26 derives an amplitude and phase error in a period in which the component of the pilot signal is included, and corrects the error in a period in which the component of the transmission signal is included. According to this modification, calibration can be executed in the frequency band of the transmission signal. That is, it suffices if the pilot signal error can be derived.

It is a figure which shows the structure of the transmitter which concerns on the Example of this invention. It is a figure which shows the structure of the pilot signal production | generation part of FIG. FIGS. 3A to 3B are diagrams illustrating signals output from the adding unit in FIG. It is a figure which shows another structure of the pilot signal production | generation part of FIG. It is a figure which shows the signal output from the addition part of FIG. It is a figure which shows the structure of the transmitter which concerns on the modification of this invention.

Explanation of symbols

  10 baseband processing unit, 12 distortion compensation unit, 14 first RF unit, 16 antenna, 18 directional coupler, 20 pilot signal generation unit, 22 addition unit, 24 second RF unit, 26 feedback correction unit, 28 distortion detection unit 100 Transmitter.

Claims (4)

An output unit that generates a transmission signal by amplifying the baseband input signal while performing frequency conversion, and then outputs the generated transmission signal;
A feedback unit that generates a baseband feedback signal by performing frequency conversion while feeding back the transmission signal output from the output unit;
Based on the feedback signal generated by the feedback unit, a derivation unit for deriving a distortion compensation coefficient for the output unit,
A compensation unit for compensating an input signal in the output unit by a distortion compensation coefficient derived by the deriving unit;
The feedback unit includes means for superimposing a pilot signal on a transmission signal before the frequency conversion, and means for correcting an error caused by frequency conversion based on the superimposed pilot signal at a subsequent stage of frequency conversion. A transmission apparatus characterized by the above.   The transmission apparatus according to claim 1, wherein the feedback unit superimposes a pilot signal in a band close to a band of the transmission signal.   The feedback unit is generated by frequency conversion on the basis of the means for performing separation from the frequency-converted transmission signal into the superimposed pilot signal component and the remaining transmission signal component, and the separated pilot signal component 3. The transmission apparatus according to claim 1, further comprising means for deriving an error and means for correcting a component of the remaining transmission signal separated by the derived error. A plurality of the output units are provided to correspond to each of a plurality of antennas,
4. The transmission device according to claim 1, wherein a plurality of the feedback unit, the derivation unit, and the compensation unit are provided so as to correspond to each of a plurality of output units. 5.

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