JP2015188246A - Transmitter and its exciter and distortion compensation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmitter in which output variation due to secular change of phase shift of an amplifier is suppressed.SOLUTION: A transmitter includes amplifiers 51, 52 for amplifying an input signal, excitation units 31, 32 including a compensating section for compensating distortion of the amplifier by giving a predistortion to the input signal, a loop D for branching the output signal from the amplifier and feeding back to the compensating section, a distributor 20 for inputting the input signal, before the predistortion is given, to respective excitation units while distributing, and a synthesizer 70 for synthesizing the output signals from respective amplifiers. The compensating section includes first through third data. The first and second data are data for compensating the non-linearity of output amplitude and output phase of the amplifier, dependent on the amplitude of the input signal. The third data is a data for compensating the non-linearity of output of the amplifier, not dependent on the amplitude of the input signal. The third data is a data reflecting the long term phase variation due to secular change, as an amount not depending on the input amplitude to the amplifier.

Description

  Embodiments described herein relate generally to a transmission apparatus applicable to a digital terrestrial broadcasting system, an exciter thereof, and a distortion compensation method.

  Compensating for nonlinear characteristics of an amplifier (Power Amplifier: PA) is a major technical point in a transmitter used in a digital broadcasting system. In a high power transmission apparatus such as a broadcasting system, a predistortion method is generally often used as a compensation method for the nonlinear characteristic. The predistortion method is a method of suppressing nonlinear distortion due to the nonlinear characteristic of the PA by previously multiplying the input characteristic of the PA with the inverse characteristic of the nonlinear characteristic of the PA and inputting it. An exciter (exciter) used in a transmission apparatus generates a modulation signal that becomes a broadcast wave and has a nonlinear distortion compensation function by a predistortion method.

  One method of detecting the predistortion reverse distortion characteristics is to input a part of the PA output to an exciter and compare it with the undistorted signal that becomes the PA input signal to detect the nonlinear characteristics of the PA. There is a method for calculating reverse distortion characteristics from the above. With this function, stable distortion compensation performance can be realized by always following the fluctuation of the nonlinear characteristic of the PA.

  By the way, a high-power transmission device includes a plurality of amplifying units, and a type that obtains high power by combining outputs of the amplifying units. This type of transmission apparatus has a problem in that output power decreases due to fluctuations in the output phase of each amplification unit before synthesis. In an existing transmission device, a combination loss due to a phase shift is suppressed to a minimum by physically adjusting a phase of a signal transmission path, a connection cable length, and the like. In addition, temperature fluctuations and temporal fluctuations are minimized by devising the circuit configuration.

JP 11-31935 A

In the existing technology, the phase shift of a plurality of amplifying units is eliminated by tracking in the hardware area. However, over time, the phase still cannot be denied, and it is inevitable that the composite loss will gradually increase.
An object of the present invention is to provide a transmitter, an exciter thereof, and a distortion compensation method in which output fluctuation due to a change with time is suppressed.

  According to the embodiment, the transmission device compensates by amplifying an input signal, a compensation unit that predistorts the input signal to compensate for distortion of the amplification unit, and a signal output from the amplification unit. And a loop for feeding back to the unit. The compensation unit includes a data generation unit and a distortion compensation unit. The data generation unit generates compensation data necessary for applying predistortion to the input signal based on a result of comparing the input signal and the output signal fed back. The distortion compensator applies predistortion to the input signal based on the compensation data. Here, the compensation data includes first to third data. The first data is data for compensating for nonlinearity of the output amplitude of the output signal that depends on the input amplitude of the input signal. The second data is data for compensating for nonlinearity of the output phase of the output signal that depends on the input amplitude. The third data is data for compensating the delay time between the input signal and the feedback signal, and includes a shift (nonlinearity) in the output phase of the output signal independent of the input amplitude.

The functional block diagram which shows an example of the transmitter concerning embodiment. The functional block diagram which shows an example of the exciters 31 and 32 shown by FIG. The schematic diagram which shows an example of the content recorded on the AM-AM compensation table 96a and the AM-PM compensation table 96b. The functional block diagram which shows the existing exciter for a comparison.

  FIG. 1 is a functional block diagram illustrating an example of a transmission apparatus according to the embodiment. The transmission apparatus shown in FIG. 1 has a format in which an input signal is distributed and input to a plurality of amplification modules, and the signals amplified by the modules are combined to obtain a large output. That is, the transmission apparatus according to the embodiment includes two systems of modules in which an amplifier and an exciter that compensates for distortion of the amplifier are connected in series. The input signal is distributed into two systems by the distributor 20 and input to each module. The output signals of the modules are synthesized by the synthesizer 70 to obtain the transmission device output. Note that a band pass filter (BPF) 80 for limiting the band of the transmission device output may be provided.

  In FIG. 1, an OFDM (Orthogonal Frequency Division Multiplex) -modulated input signal from the OFDM modulator 10 is distributed into two systems by a distributor 20 and input to exciters 31 and 32. The exciters 31 and 32 frequency-convert the input signal and give predistortion for distortion compensation in the amplifiers 51 and 52 to the input signal. A local signal for frequency conversion is generated in the local oscillator 60 and supplied to the exciters 31 and 32 via the branching unit 40. The outputs of the exciters 31 and 32 are respectively input to amplifiers 51 and 52 connected to the subsequent stages, and are individually amplified.

  The outputs of the amplifiers 51 and 52 are branched into two systems by the branching section D. One of these signals is input to the synthesizer 70 for power synthesis. As a result, a radio band transmission signal is output at the transmission output level. The band of this transmission signal is limited by a band pass filter (BPF) 80 and is output as the output of the transmission apparatus. The other signals branched by the branching part D are fed back to the exciters 31 and 32, respectively, and a signal loop is formed.

  FIG. 2 is a functional block diagram showing an example of the exciters 31 and 32 shown in FIG. At least three systems of signals are input to the exciters 31 and 32. That is, an OFDM signal (OFDM input) from the OFDM modulator 10, a feedback signal (feedback input) from the branching section D, and a local signal from the local oscillator 60.

  Of these, the OFDM input is input to the IF signal processing unit 91 and subjected to signal processing in an intermediate frequency band. The output of the IF signal processing unit 91 is input to the distortion compensation unit 92, and amplitude control and phase control are performed to compensate for distortion of the amplifiers 51 and 52 in the subsequent stage (FIG. 1). That is, the distortion compensation unit 92 compensates for distortion of the amplifiers 51 and 52 by applying predistortion to the input signal. For this compensation, compensation data is generated by the data generation unit 100.

  The output of the distortion compensation unit 92 is input to the frequency conversion unit 93 and the delay estimation / compensation unit 95 of the data generation unit 100. The frequency converter 93 frequency-converts the output of the distortion compensator 92 in accordance with the frequency of the local signal, and the frequency-converted signal is input as an exciter output to the subsequent amplifier.

  The feedback signal is input to the delay estimation / compensation unit 95 of the data generation unit 100 via the feedback signal processing unit 94. The delay estimation / compensation unit 95 receives the output of the distortion compensation unit 92 and the output of the feedback signal processing unit 94 as inputs. The delay estimation / compensation unit 95 detects a delay time and a phase shift between the OFDM signal and the feedback signal on the basis of the output of the distortion compensation unit 92 (that is, the OFDM signal: equivalent to the input signal to the transmission device), At the same time, a process for adjusting the deviation is performed.

  For this processing, the delay estimation / compensation unit 95 calculates a relative delay amount and a phase shift amount between the OFDM signal and the feedback signal based on a result of comparing both signals. The obtained delay / phase information is given to the distortion estimation unit 96 as one piece of compensation data.

  Next, the two signals whose delay time and phase shift are combined by the delay estimation / compensation unit 95 are input to the distortion estimation unit 96, and the input amplitude versus output amplitude characteristic, which becomes distortion characteristics from the difference between the two signals, Data of input amplitude versus output phase characteristics is detected. Thus, necessary compensation data for applying predistortion to the input signal is generated from the input signal and the output signal fed back. That is, the data generation unit 100 generates compensation data necessary for applying predistortion to the input signal based on the result of comparing the input signal and the output signal fed back.

  The compensation data includes at least first to third data. Of these, the first data is data for compensating non-linearity of the output amplitude of the output signals of the amplifiers 51 and 52, which depends on the input amplitude of the input signal. The second data is data for compensating for nonlinearity of the output phase of the output signals of the amplifiers 51 and 52, which depends on the input amplitude of the input signal. The third data is data for compensating for nonlinearity of the output phase of the amplifiers 51 and 52 that does not depend on the input amplitude of the input signal. In particular, the third data is positioned as an amount that does not depend on the input amplitude to the amplifiers 51 and 52, and is data that reflects, for example, long-term phase fluctuations due to changes over time.

  The distortion estimation unit 96 includes an AM-AM compensation table 96a, an AM-PM compensation table 96b, and a rewrite processing unit 96c as functional blocks according to the embodiment. Of these, the rewrite processing unit 96c rewrites the contents of the AM-PM compensation table 96b to reflect the third data.

  FIG. 3 is a schematic diagram showing an example of contents recorded in the AM-AM compensation table 96a and the AM-PM compensation table 96b. The AM-AM compensation table 96a shown in FIG. 3A is data in which output amplitude characteristics with respect to input amplitude to the amplifier are tabulated. The content recorded in this table reflects the first data.

  The AM-PM compensation table 96b shown in FIG. 3B is data in which the output phase characteristics with respect to the input amplitude to the amplifier are tabulated. The content recorded in this table reflects the second data.

  FIG. 3C shows the contents of the AM-PM compensation table 96b changed by the rewrite processing unit 96c. That is, the rewrite processing unit 96c rewrites the contents of the AM-PM compensation table 96b by adding the third data, that is, the phase fluctuation amount independent of the input amplitude, to the numerical value of the AM-PM compensation table 96b. Thereby, if the AM-PM compensation table 96b after rewriting is used, in addition to the phase fluctuation depending on the input amplitude, the phase fluctuation not depending on the input amplitude can be compensated.

  That is, the data generation unit 100 estimates the distortion component of the amplifier and calculates its AM-AM (amplitude-amplitude) characteristics and AM-PM (amplitude-phase) characteristics. The predistortion type amplifier picked up in the embodiment cancels distortion components of the amplifier by applying a characteristic opposite to the above characteristic to the input signal. In the embodiment, by using this function, distortion compensation is performed based on the AM-PM compensation table 96b offset by a phase fluctuation reflecting a change with time, so that the phase fluctuation is canceled together with the distortion of the amplifier. It becomes possible.

  Note that the offset amount of the AM-PM compensation table 96b may be positive or negative as shown in FIG. Further, the absolute value of the offset amount also fluctuates so as to follow the change with time.

  FIG. 4 is a functional block diagram showing an existing exciter for comparison. The existing exciter does not include a path for providing the delay / phase information calculated by the delay estimation / compensation unit 95 to the distortion estimation unit 96. Further, the rewrite processing unit 96c is not provided. Therefore, it is impossible to follow the phase fluctuation accompanying the change with time.

  In contrast, in the embodiment, data indicating the delay amount and the phase change amount calculated by the delay estimation / compensation unit 95 is passed to the distortion estimation unit 96, and the contents of the AM-PM compensation table 96b used for distortion compensation are offset. I try to let them. This offset amount reflects phase fluctuations due to changes over time. Therefore, by performing distortion compensation using the AM-PM compensation table 96b, the output phase fluctuation at the amplifier is canceled and the output phase is kept constant.

  In the embodiment, the distortion compensation function provided in the exciter is used. Therefore, it is possible to effectively suppress the phase fluctuation and prevent the deterioration of the synthesis loss without adding a complicated circuit. Furthermore, the number of amplifiers can be easily increased or decreased, and it is possible to easily cope with a change in specifications required for the output of the transmitter. Accordingly, it is possible to provide a transmission apparatus, an exciter, and a distortion compensation method in which output fluctuation due to a change with time is suppressed.

  Although an embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 10 ... OFDM modulator, 20 ... Divider, 31, 32 ... Exciter, 40 ... Branch part, 51, 52 ... Amplifier, 60 ... Local oscillator, 70 ... Synthesizer, 80 ... Band pass filter (BPF), D ... Branch unit 91 IF signal processing unit 92 Distortion compensation unit 93 Frequency conversion unit 94 Feedback signal processing unit 95 Delay estimation / compensation unit 96 Distortion estimation unit 96a AM-AM compensation table 96b AM-PM compensation table 96c Rewrite processing unit 100 Data generation unit

According to the embodiment, the transmitting apparatus before and amplifier for amplifying an input signal applied to predistortion, a compensation unit for compensating for distortion of the amplifier gives predistortion to the input signal, the amplifier portion And a loop for branching the output signal from and feeding back to the compensation unit. The compensation unit includes a data generation unit and a distortion compensation unit. The data generation unit includes first data for compensating nonlinearity of the output amplitude of the output signal depending on the input amplitude of the input signal before being given the predistortion, and the output signal depending on the input amplitude The second data for compensating the nonlinearity of the output phase and the third data for compensating the nonlinearity of the output phase independent of the input amplitude are generated. The first data is generated based on a result of comparing the input signal before being given the predistortion and the feedback output signal. The second data is generated based on a result of comparing the input signal before being given the predistortion and the feedback output signal. The third data is a transmission device that generates the third data based on the first data and the second data .

Claims (8)

An amplifier for amplifying the input signal given the predistortion;
A compensation unit that applies the predistortion to the input signal to compensate for distortion of the amplification unit;
A loop for branching the output signal from the amplification unit and feeding back to the compensation unit;
The compensation unit
First data for compensating nonlinearity of the output amplitude of the output signal depending on the input amplitude of the input signal before being given the predistortion, and nonlinearity of the output phase of the output signal depending on the input amplitude The second data for compensating the characteristic and the third data for compensating the nonlinearity of the output phase independent of the input amplitude are fed back to the input signal before being given the predistortion. A data generation unit for generating the output signal based on the comparison result;
A transmission apparatus comprising: a distortion compensation unit that applies the predistortion to the input signal based on the first to third data. The data generator is
A first table that records the characteristics of the output amplitude with respect to the input amplitude, reflecting the first data;
A second table that records the characteristics of the output phase with respect to the input amplitude, reflecting the second data;
The transmission apparatus according to claim 1, further comprising: a rewrite processing unit that rewrites the contents of the second table to reflect the third data. A plurality of modules in which the amplification unit and the compensation unit for compensating for distortion of the amplification unit are connected in series,
Further, a distributor for distributing the input signal before being given the predistortion to a plurality of the input signals,
The transmission apparatus according to claim 1, further comprising a combiner that combines output signals of the respective modules.   The transmission device according to any one of claims 1 to 3, further comprising a band-pass filter that limits a signal band of the output stage. In an exciter used in a transmission device including an amplification unit that amplifies an input signal given predistortion, and a loop that branches and feeds back an output signal from the amplification unit,
First data for compensating nonlinearity of the output amplitude of the output signal depending on the input amplitude of the input signal before being given the predistortion, and nonlinearity of the output phase of the output signal depending on the input amplitude The second data for compensating the characteristic and the third data for compensating the nonlinearity of the output phase independent of the input amplitude are fed back to the input signal before being given the predistortion. A data generation unit for generating the output signal based on the comparison result;
An exciter comprising: a distortion compensator that applies the predistortion to the input signal based on the first to third data. The data generator is
A first table that records the characteristics of the output amplitude with respect to the input amplitude, reflecting the first data;
A second table that records the characteristics of the output phase with respect to the input amplitude, reflecting the second data;
The exciter of Claim 5 provided with the rewriting process part which rewrites the content of the said 2nd table reflecting the said 3rd data. In a distortion compensation method for compensating for distortion of an amplifier by applying predistortion to an input signal input to an amplifier included in a transmission device,
The transmission apparatus compensates for nonlinearity of the output amplitude of the output signal that depends on the input amplitude of the input signal before being subjected to the predistortion, and the output signal that depends on the input amplitude The second data for compensating for the nonlinearity of the output phase and the third data for compensating for the nonlinearity of the output phase independent of the input amplitude are input signals before being given the predistortion. And the feedback output signal is generated based on the result of comparison,
A distortion compensation method, wherein the transmission device applies the predistortion to the input signal based on the first to third data. Said generating is
The transmitter records the characteristics of the output amplitude with respect to the input amplitude, which reflects the first data, in a first table,
The transmitter records, in a second table, a characteristic of nonlinearity of the output phase with respect to the input amplitude that reflects the second data;
The distortion compensation method according to claim 7, wherein the transmission device rewrites the content of the second table to reflect the third data.