JP2012142840A - Distortion compensation circuit device - Google Patents

Abstract

Disclosed is distortion compensation in a plurality of frequency bands.
A distortion compensation circuit device connected to a preceding stage of a broadband amplifier and configured to compensate for distortion of a signal output from the broadband amplifier, the input signal being input, The linearizers LRZ1, 2, and 3 are provided as distortion compensation circuits for generating inverse distortion of the distortion generated in the broadband amplifier 10, and a plurality of these linearizers LRZ1, 2, and 3 are arranged in parallel corresponding to different frequency bands. These are used by switching them according to the frequency value of the input signal. Further, in order to efficiently cancel the distortion generated in the broadband amplifier 10 by the reverse distortion, the variable gain amplifier 2 for adjusting the gain of the signal and adjusting to an appropriate signal output is used in front of the broadband amplifier 10. This further improves the distortion characteristics.
[Selection] Figure 3

Description

  The present invention relates to a distortion compensation circuit device, and more particularly to distortion compensation for a low distortion amplifier that is applied to a satellite communication amplifier, a mobile communication amplifier, and a terrestrial microwave communication amplifier to compensate for amplitude nonlinearity and phase nonlinearity. The present invention relates to a circuit device.

  In order to reduce the size and cost of communication amplifiers, the use of a plurality of frequency bands with a common amplifier is increasing. An amplifier used for such an application may be a wideband amplifier that covers the entire frequency band to be used, such as switching the matching circuit of the amplifier in accordance with the frequency band to be used, such as a reconfigurable amplifier. In addition to the efficiency and output of the amplifier, distortion characteristics are important characteristics required for the communication amplifier. If the distortion characteristic is not more than a certain level, communication cannot be performed. There is a distortion compensation circuit as an apparatus for improving distortion characteristics. In order to compensate for distortion in a plurality of frequency bands, the frequency characteristics of the distortion compensation circuit must also be wide. In principle, there is an analog predistorter method as a device capable of compensating for distortion in a wide band. Hereinafter, as a conventional example, a diode linearizer using an analog predistorter system will be described.

  First, as a conventional example 1, an apparatus described in Patent Document 1 is given. In the distortion compensation circuit described in Patent Document 1, a circuit in which a resistor and a DC power source are connected in series, a circuit including at least one of an inductor and a resistor, and a forward-biased diode are connected in series. The circuit is connected in parallel to the signal path, and capacitors are connected in series on the input side and output side of the signal path. In this configuration, the gain Gain increases and the phase Phase delays with respect to the increase of the input power Pin. By changing the DC voltage, the gain and pass phase characteristics of the distortion compensation circuit can be easily adjusted. Further, by changing the resistance value, it is possible to adjust gain, pass phase characteristics, and sensitivity to input power.

  Further, as a conventional example 2, an apparatus described in Patent Document 2 is cited. In the distortion compensation circuit described in Patent Document 2, a circuit in which a resistor and a DC power source are connected in series, a circuit including at least one of an inductor and a resistor, and a forward-biased diode are connected in series. The circuit is connected in series to the signal path, and a capacitor is connected in series on the input side and output side of the signal path. In this configuration, the gain Gain decreases and the phase Phase advances as the input power Pin increases. Also in this configuration, similarly to the conventional example 1, the gain and pass phase characteristics of the distortion compensation circuit can be easily adjusted by changing the DC voltage. Further, by changing the resistance value, it is possible to adjust gain, pass phase characteristics, and sensitivity to input power.

  Further, as a conventional example 3, an apparatus described in Patent Document 3 is cited. The distortion compensation circuit described in Patent Document 3 is biased in the reverse direction with a circuit in which a resistor and a DC power supply are connected in series, a circuit including at least one of an inductor and a resistor, and a forward-biased diode. A circuit in which the diodes are connected in series is connected in series to the signal path, and a capacitor is connected in series on the input side and output side of the signal path. In the configuration, the gain Gain is once decreased with respect to the increase of the input power Pin, and the gain Gain is increased when the input power Pin is further increased. Further, the phase Phase is once advanced with respect to the increase of the input power Pin, and the characteristic that the phase Phase is delayed when the input power Pin is further increased is obtained. Also in this configuration, the gain and pass phase characteristics of the distortion compensation circuit can be easily adjusted by changing the DC voltage, as in the conventional examples 1 and 2. Further, by changing the resistance value, it is possible to adjust gain, pass phase characteristics, and sensitivity to input power.

Japanese Patent No. 3335907 Japanese Patent No. 3995121 Japanese Patent No. 4319681

  However, in the conventional examples 1, 2, and 3 described in Patent Documents 1, 2, and 3, when a plurality of frequency bands are used in a common amplifier, distortion characteristics differ for each frequency band. In some cases, the frequency band could not be completely compensated. This will be described using a broadband amplifier as an example. FIG. 1 shows (a) gain characteristics, (b) phase characteristics, and (c) distortion characteristics with respect to the output power of the wideband amplifier at three frequencies (f1, f2, and f3). At the frequency f1, the gain characteristic increases with an increase in the output power Pout, and the phase characteristic is delayed. The frequency f2 has a flat gain characteristic and a phase characteristic with respect to the increase in the output power Pout. In the frequency f3, the gain characteristic decreases as the output power Pout increases, and the phase characteristic further advances as compared with the frequency f2. When used in communication applications, the linearity of the amplifier is important, and distortion generated in the amplifier becomes a problem. For example, when the communication standard is set such that the specified output is A or more and the distortion is B or less, the frequency f2 satisfies the communication standard as shown in FIG. f1 and f3 are not satisfied. In such a case, a diode linearizer may be used as a means for improving linearity. The gain characteristics and phase characteristics of Conventional Examples 1, 2, and 3 are shown in FIGS. 2 (a), 2 (b), and 2 (c), respectively. In order to increase the linearity of the frequency f1, it is optimal to use the conventional examples 2 and 3. However, the frequency f3 further deteriorates the linearity and the linearity of the frequency f2 also deteriorates. On the other hand, Conventional Example 1 is optimal for increasing the linearity of the frequency f3. In this case, however, the frequency f1 further deteriorates the linearity, and the linearity of the frequency f2 also deteriorates.

  As described above, in the conventional examples 1, 2, and 3, if the linearity of one frequency is increased, the linearity of other frequencies is deteriorated. Therefore, a single diode linearizer completely compensates for a plurality of frequency bands. There was a problem that could not be done.

  The present invention has been made to solve such a problem, and enables distortion compensation so that a plurality of frequency bands can be compensated, and the frequency bands between the respective frequency bands can be used for communication applications. An object is to obtain a circuit device.

  The present invention relates to a distortion compensation circuit device for compensating for distortion of an output signal of an amplifier connected to a preceding stage of the amplifier, and receiving an input signal to reverse distortion generated by the amplifier. For the input signal, a plurality of the distortion compensation circuits are arranged in parallel corresponding to different frequency bands, and the distortion compensation is performed according to the frequency value of the input signal. It is a distortion compensation circuit device characterized by switching circuits.

  The present invention relates to a distortion compensation circuit device for compensating for distortion of an output signal of an amplifier connected to a preceding stage of the amplifier, and receiving an input signal to reverse distortion generated by the amplifier. For the input signal, a plurality of the distortion compensation circuits are arranged in parallel corresponding to different frequency bands, and the distortion compensation is performed according to the frequency value of the input signal. Since the distortion compensation circuit device is characterized in that the circuits are switched and used, a plurality of frequency bands can be compensated, and the frequency bands between the respective frequency bands can be used for communication purposes.

It is explanatory drawing which showed the gain characteristic with respect to the output power of a wideband amplifier, a phase characteristic, and the distortion characteristic with the graph about several frequency band. It is explanatory drawing which showed the gain characteristic and phase characteristic at the time of using the diode linearizer in the prior art examples 1, 2, and 3 with the graph. It is the block diagram which showed the structure of the distortion compensation circuit apparatus based on Embodiment 1 of this invention. It is explanatory drawing which showed the gain characteristic and phase characteristic of each linearizer provided in the distortion compensation circuit apparatus based on Embodiment 1 of this invention with the graph. It is explanatory drawing which showed the distortion characteristic of the wideband amplifier before and behind distortion compensation for every frequency band in the distortion compensation circuit apparatus which concerns on Embodiment 1 of this invention with the graph. It is explanatory drawing which showed the distortion characteristic of the wideband amplifier after the distortion compensation in each frequency band in the distortion compensation circuit apparatus which concerns on Embodiment 1 of this invention with the graph. In the distortion compensation circuit device according to the first embodiment of the present invention, it is an explanatory diagram showing gain characteristics and phase characteristics in the case of a frequency separated from the frequency f1 by a certain fixed frequency. It is explanatory drawing which showed the gain characteristic and phase characteristic at the time of using the diode linearizer in the distortion compensation circuit apparatus based on Embodiment 1 of this invention with the graph. It is explanatory drawing which showed the distortion characteristic at the time of applying a several bias voltage to each linearizer in the distortion compensation circuit apparatus based on Embodiment 1 of this invention with the graph. It is the block diagram which showed the structure of the distortion compensation circuit apparatus based on Embodiment 2 of this invention. It is explanatory drawing which showed the distortion characteristic at the time of switching with each filter in the distortion compensation circuit apparatus based on Embodiment 2 of this invention with the graph. It is the block diagram which showed the structure of the distortion compensation circuit apparatus based on Embodiment 3 of this invention.

  Embodiments of the distortion compensation circuit device of the present invention will be described below with reference to the drawings.

Embodiment 1 FIG.
FIG. 3 is a diagram showing an example of the configuration of the distortion compensation circuit device according to the first embodiment of the present invention. The distortion compensation circuit device according to the first embodiment has a configuration in which the distortion compensation circuit unit 1 is placed in front of the broadband amplifier 10 as shown in FIG. The distortion compensation circuit device according to the first embodiment includes a distortion compensation circuit unit 1 and a variable gain amplifier 2 as shown in FIG. The distortion compensation circuit unit 1 includes switches 1 and 2 (reference numerals 3 and 4) and a linearizer bank 5 as shown in FIG. The linearizer bank 5 is connected between the switch 1 (symbol 3) and the switch 2 (symbol 4). A plurality of linearizers (LRZ1, LRZ2, LRZ3) as distortion compensation circuits are provided.

  The switch 1 (reference numeral 3) is provided with one input terminal for inputting a signal and three output terminals for outputting the signal to the linearizer bank 5. These output terminals are provided in the same number as the number of linearizers in the linearizer bank, and are connected one-to-one to each linearizer. A control circuit (not shown) is connected to the switch 1 (reference numeral 3). The control circuit detects the frequency band of the signal input to the switch 1 (reference numeral 3), determines which one of the linearizers corresponds to the frequency band, and sets a control voltage for switching the switch based on the determination. Apply to switch 1 (symbol 3). Thereby, the switch 1 (reference numeral 3) performs an output terminal switching operation so that a signal can be output to the linearizer corresponding to the frequency band of the input signal. Specifically, by the switching operation, the switch 1 (symbol 3) is connected from the output terminal connected to the linearizer LRZ1 in the linearizer bank 5 when the frequency of the signal input to the switch 1 (symbol 3) is f1. In the case of f2, a signal is output from an output terminal connected to the linearizer LRZ2, and in the case of f3, a signal is output from an output terminal connected to the linearizer LRZ3.

  Further, the switch 2 (reference numeral 4) is provided with three input terminals for inputting a signal from the linearizer bank 5 and one output terminal for outputting the signal to the variable gain amplifier 2. . These input terminals are provided in the same number as the number of linearizers in the linearizer bank, and are connected one-to-one to each linearizer. A control circuit is also connected to the switch 2 (reference numeral 4), whereby a switch switching control voltage is applied to perform a switching operation. That is, when a signal from the linearizer bank 5 is input to any one of the input terminals of the switch 2 (reference 4), the control circuit applies a control voltage for switching the switch. In 4), a switching operation for connecting the input terminal to which the signal is input and the output terminal for outputting the signal is performed, and the signal input to the switch 2 is output to the variable gain amplifier 2 from the output terminal. Is done.

  Next, the overall operation of the distortion compensation circuit device according to the first embodiment will be briefly described. First, when a signal is input to the switch 1 (symbol 3), the control circuit controls the switch 1 (symbol 3) to perform the switching operation described above according to the frequency of the signal. The signal is input to one of the linearizers LRZn (n = 1, 2, 3) in the corresponding linearizer bank 5. When a signal is input to the linearizer LRZn, the linearizer LRZn generates a reverse distortion of the distortion generated in the broadband amplifier 10 for the signal and inputs the signal to the switch 2. After passing through the switch 2, the signal output from the switch 2 is input to the variable gain amplifier 2. In the variable gain amplifier 2, in order to effectively cancel out the distortion generated by the wideband amplifier 10 due to the reverse distortion generated by the linearizer, the gain of the input signal is adjusted and adjusted to an appropriate signal output. The signal adjusted to an appropriate output by the variable gain amplifier 2 is input to the broadband amplifier 10. In the wideband amplifier 10, the distortion generated in the wideband amplifier 10 is canceled out by the reverse distortion generated in the linearizer, and the distortion characteristics of the signal are reduced.

  Here, the case where the broadband amplifier 10 has the characteristics shown in FIG. 1 will be described in detail below. A linearizer is prepared in which the gain characteristics and phase characteristics of the wideband amplifier 10 are reversed in each frequency band used for the input signal. The linearizers LRZ1, LRZ2, and LRZ3 are installed in the linearizer bank 5 and connected in parallel. To do.

  As shown in FIG. 1, the gain characteristic of the broadband amplifier 10 having the frequency f1 has an expansion characteristic (a characteristic in which the gain increases as the output power increases and the gain decreases as the output further increases), and the phase characteristic corresponds to the output characteristic. It becomes a characteristic that it is delayed once with respect to the electric power and proceeds when the output becomes larger. The gain characteristic of the frequency f2 is substantially constant with respect to the output power and becomes a decreasing characteristic near saturation, and the phase characteristic also becomes a characteristic in which the phase advances near saturation. The gain characteristic of the frequency f3 gradually decreases with respect to the output power, and the phase characteristic gradually advances with respect to the output power.

  In the first embodiment, linearizers LRZ1, LRZ2, and LRZ3 shown in FIG. 3C are used as linearizers corresponding to the frequencies f1 to f3 having such characteristics, respectively. FIGS. 4A, 4B, and 4C show gain characteristics and phase characteristics of the linearizers LRZ1, LRZ2, and LRZ3, respectively. The broken lines in FIGS. 4A, 4 </ b> B, and 4 </ b> C indicate ideal reverse characteristics for the broadband amplifier 10. 4A, 4B, and 4C, the actual characteristics of the linearizers LRZ1, LRZ2, and LRZ3 used in the first embodiment are indicated by solid lines. All the solid lines are considerably along the broken line, but when an analog predistorter using a diode is used, it cannot completely match the distortion characteristics of the amplifier. This is because it is not possible to create perfectly matching distortion characteristics with different semiconductor elements. Therefore, the deviation between the solid line and the broken line shown in FIG. FIG. 5 shows the distortion characteristics of the broadband amplifier 10 before and after distortion compensation at frequencies f1, f2, and f3. The broken line is the characteristic before distortion compensation, and the solid line is the characteristic after distortion compensation. As a communication standard, when the prescribed output is A or more and the distortion is B or less, the frequencies f1 and f3 do not satisfy the communication regulation before distortion compensation, but satisfy after the compensation. Although the frequency f2 is satisfied for a while before distortion compensation, the distortion characteristics are further improved after compensation. Therefore, as a result, it can be seen that, at any of the frequencies f1, f2, and f3, the distortion is compensated to a level that satisfies the communication standard after the distortion compensation.

  When the distortion is compensated as described above, as shown in FIG. 6, the frequency band 1a, the frequency band 2a, and the frequency band 3a all have a distortion of B or less, satisfying the communication standard and used for communication applications. it can. Here, the frequency bands 1a, 2a, and 3a are frequency bands having a predetermined width centered on the frequencies f1, f2, and f3, respectively. The widths of these frequency bands may be the same or different. Since the gain characteristic and the phase characteristic of the wideband amplifier 10 change according to the frequency, even if distortion compensation is performed with a certain linearizer, the frequency band that can be compensated by that is limited. Therefore, in FIG. 6, distortion compensation is not performed between the frequency bands 1a and 2a or between the frequency bands 2a and 3a. FIG. 7 shows gain characteristics and phase characteristics of a frequency separated from the frequency f1 by a certain fixed frequency. The broken line characteristic is a frequency shifted by a fixed frequency from the frequency f1 in a direction approaching the frequency f2, and the dashed dotted characteristic is a shift of the fixed frequency from the frequency f1 by a fixed frequency in a direction away from the frequency f2. Compared to FIG. 1, it can be seen that the characteristics of the broken line are similar to f2.

  A linearizer using a diode can change gain characteristics and phase characteristics by changing an applied bias voltage. FIG. 8 shows the characteristics. FIG. 8 shows the case of the linearizer LRZ1. In FIG. 8, the broken line indicates a case where the bias voltage applied to the diode is reduced, and the one-dot broken line indicates a case where the bias voltage is increased. When the bias voltage is reduced, it becomes close to the inverse characteristic of the broken line in FIG. Therefore, by changing the bias voltage applied to the diode, it is synonymous with switching the distortion compensation circuits in parallel, or even for frequency bands that cannot be compensated by simply switching the distortion compensation circuits in parallel. become able to. When three patterns of bias voltages are applied to the linearizers LRZ1 to LRZ3, as shown in FIG. 9, the frequency bands 1a, 1b, 1c, the frequency bands 2a, 2b, 2c, and the frequency bands 3a, 3b, 3c are respectively set. Since distortion can be compensated and the distortion is equal to or less than distortion B in all frequency bands around the frequencies f1 to f3, the communication standard is satisfied. Furthermore, in the example of FIG. 9, all the frequency bands 1b to 3c can be covered, and thus by adjusting the bias voltage, the periphery (1a, 2a, 3a) of each frequency f1, f2, f3 ) As well as the frequency bands (1b, 1c, 2b, 2c, 3b, 3c) between those frequency bands (1a, 2a, 3a) that could not be compensated for in FIG. 6 can be used for communication purposes. Thus, distortion compensation can be performed. From the above, only the frequency bands 1a, 2a, 3a can be used for communication only by using linearizers for individual frequency bands, but by switching a plurality of linearizers in parallel and switching those linearizers, And by changing the bias voltage applied to these linearizers, distortion compensation can be performed over a very wide band. That is, using a plurality of linearizers in parallel enables distortion compensation for all the bands of the broadband amplifier 10.

  In the first embodiment, the switching of switches 1 and 2 (reference numerals 3 and 4), the switching of the bias voltage to the linearizer, and the gain adjustment of the variable gain amplifier 2 are created in advance for each frequency band. For example, in the frequency band 1a, the switches 1 and 2 are switched to the linearizer LRZ1, the bias voltage to the linearizer LRZ1 is V = 1.5V, the gain of the variable gain amplifier 2 is 5 dB, etc. Note: Since a table is created for each frequency band 1a to 3c, nine tables can be created in the example of FIG. 9), and the table to be used is automatically switched according to the frequency band to be used. Like that. As a result, highly accurate control is possible while suppressing the load on the control circuit. If the contents of the table can be updated (fine adjustment of voltage and gain values, addition of a table, etc.) according to the situation, the convenience is further improved.

  In the above description of the first embodiment, the functions of the linearizers LRZ1, LRZ2, and LRZ3 are specialized for each of the frequencies f1 to f3. However, the present invention is not limited to this, and the effectiveness of one linearizer is increased. It is also possible to use for two or more frequency bands. Further, even if there are two or more broadband amplifiers 10 connected in the subsequent stage, the distortion compensation circuit of the first embodiment can be used similarly. In addition, here, an example in which the distortion compensation circuit device according to the first embodiment is applied to the wideband amplifier has been described. It is.

  In the first embodiment, three frequencies f1 to f3 have been described as examples of frequency bands. However, the number of frequency bands is naturally not limited to this, and the present invention is not limited to two or more arbitrary frequencies. Needless to say, the present invention is applicable to the case where a plurality of frequency bands are used.

  As described above, in the first embodiment, two or more linearizers LRZ1 to LRZ1 to LRZ1 to LRZ1 are provided in front of the wideband amplifier (or narrowband amplifier) as a distortion compensation circuit so as to support a plurality of frequency bands. Since these linearizers are connected in parallel, and which linearizer is used is automatically switched by switches 1 and 2 based on the frequency band of the input signal, a plurality of frequency bands Distortion can be compensated. In addition to switching the linearizer, the bias voltage applied to the diode provided in the linearizer is also adjusted, so that a wider frequency band can be compensated, and only in each frequency band. In addition, it is possible to obtain an effect that the frequency bands between the respective frequency bands can be used for communication purposes. Further, since the variable gain amplifier 2 is provided in the subsequent stage of the distortion compensation circuit unit 1 to adjust the gain to an appropriate signal output and then input to the wideband amplifier 10, the inverse generated by the linearizer Due to the distortion, the distortion generated in the broadband amplifier 10 can be canceled out efficiently, and the distortion characteristics of the signal output from the broadband amplifier 10 can be reduced. Furthermore, switching of switches 1 and 2, switching of the bias voltage, and gain adjustment of the variable gain amplifier are performed using a table prepared in advance, so high-precision control can be performed while suppressing the load on the control circuit. Can be realized.

Embodiment 2. FIG.
FIG. 10 is a diagram showing an example of the configuration of a distortion compensation circuit device according to Embodiment 2 of the present invention. As shown in FIG. 10A, the distortion compensation circuit device according to the second embodiment includes a distortion compensation circuit unit 1 and a variable gain amplifier 2, and the distortion compensation circuit unit 1 serves as a wideband amplifier 10. This is a pre-configuration. The configuration of the second embodiment is obtained by replacing the switches 1 and 2 (reference numerals 3 and 4) of the first embodiment with filters 1 and 2 (reference numerals 13 and 14), respectively. Since other configurations are the same as those in the first embodiment, the description thereof is omitted here.

  As shown in FIG. 10B, the filter 1 (reference numeral 13) is provided with three filters 13a, 13b, and 13c corresponding to the frequencies f1, f2, and f3. Further, the filter 2 (reference numeral 14) is provided with three filters 14a, 14b and 14c corresponding to the respective frequencies f1, f2 and f3. Accordingly, the filters 13a and 14a are filters that pass only signals in the frequency band of the frequency f1, the filters 13b and 14b are filters that pass only signals in the frequency band of the frequency f2, and the filters 13c and 14c are frequency bands of the frequency f3. It is a filter that passes only the signal. As described above, the filters 13a and 14a, the filters 13b and 14b, and the filters 13c and 14c pass signals in different frequency bands, and do not pass signals in other frequency bands. Specifically, the filters 13a and 14a are configured by, for example, a low-pass filter (LPF), the filters 13b and 14b are configured by, for example, a band-pass filter (BPF), and the filters 13c and 14c are configured by a high-pass filter (HPF). ).

  The filter 1 (reference numeral 13) is provided with the same number of filters 13a, 13b, 13c as the number of linearizers in the linearizer bank 5, and each of the filters 13a, 13b, 13c is provided with each of the linearizers LRZ1, LRZ2, LRZ3. Are connected in a one-to-one relationship, and a signal that has passed through it is input to a corresponding linearizer. Similarly, the filter 2 (reference numeral 14) is provided with the same number of filters 14a, 14b, 14c as the number of linearizers in the linearizer bank 5, and each filter 14a, 14b, 14c is provided with each linearizer. LRZ1, LRZ2, and LRZ3 are connected in a one-to-one relationship, and when a signal from the linearizer is input, the signal is input to variable gain amplifier 2.

  Next, the operation of the distortion compensation circuit device according to the second embodiment will be briefly described. Since the signal input to the filter 1 (symbol 13) can pass only the filter corresponding to the frequency band of the signal among the three filters 13a, 13b, and 13c, it passes through the filter corresponding to the used frequency. Thereby, the signal path is automatically switched, and the signal that has passed through the filter is the linearizer LRZn (n = 1, 2) corresponding to the frequency band of the signal of the linearizers LRZ1, LRZ2, and LRZ3 in the linearizer bank 5. , 3). The signal input to the linearizer LRZn of the linearizer bank 5 causes the inverse distortion of the distortion of the broadband amplifier 10 to be generated by the linearizer and input to the filter 2 (reference numeral 14). Since the signal input to the filter 2 (symbol 14) can pass only the filter corresponding to the frequency band of the signal among the three filters 14a, 14b, and 14c, only the filter corresponding to the used frequency is passed. After passing through the filter 2 (symbol 14), the signal is input to the variable gain amplifier 2. In the variable gain amplifier 2, the gain is adjusted and adjusted to an appropriate signal output in order to efficiently cancel the reverse distortion generated by the linearizer and the distortion generated by the broadband amplifier 10. The signal adjusted to an appropriate output is input to the broadband amplifier 10, and the distortion generated in the broadband amplifier 10 is canceled out by the reverse distortion generated by the linearizer, so that the distortion characteristic of the signal output from the broadband amplifier 10 is small. Become.

  Here, the case where the broadband amplifier 10 has the characteristics shown in FIG. 1 will be described in detail below. As described in the first embodiment, the linearizers LRZ1, LRZ2, and LRZ3 arranged in parallel are switched in accordance with the frequency band of the signal, and the bias voltage of the linearizers LRZ1, LRZ2, and LRZ3 is adjusted, so that the wideband amplifier Distortion characteristics can be satisfied in all frequency bands from 10 frequencies f1 to f3. The filters 1 and 2 (reference numerals 13 and 14) will be described in detail with reference to FIG. A range of frequencies in which distortion compensation can be performed by the linearizer LRZ1 is a region I. Similarly, the ranges of frequencies that can be compensated by the linearizers LRZ2 and LRZ3 are defined as a region II and a region III, respectively. When the frequency of the signal is within the range of region I, it is desirable that the linearizers LRZ2 and LRZ3 do not operate. That is, when the frequency of the signal is within the range of the region I, the filters 13b and 13c provided for the region II and the region III must not pass the signal of the region I. Similarly, when the frequency of the signal is within the range of the region II, the filters 13a and 13c provided for the region I and the region III should not pass the signal of the region II. Similarly, when the frequency of the signal is within the range of the region III, the filters 13a and 13b provided for the region I and the region II should not pass the signal of the region III. As a filter of a solution satisfying such a restriction, the filter 13a for the region I is a low pass filter (LPF), the filter 13b for the region II is a band pass filter (BPF), and the filter 13c for the region III is a high pass filter (HPF). Can satisfy the solution.

  In the first embodiment described above, it is necessary to switch the switches 3 and 4 in accordance with the operating frequency. However, in the configuration of the second embodiment, by adopting such a configuration, a signal is automatically generated in accordance with the operating frequency. The path changes (the filters 13a, 13b, and 13c pass only the signals in the corresponding frequency band and do not add the signals in the other frequency bands, so that the signal passes through the filter that can pass. Therefore, the signal path changes naturally.) Thus, since it is not necessary to switch the signal path by the control of the control circuit and the signal path is naturally changed, there is an advantage that the number of control points is reduced and the load on the control circuit is reduced. Furthermore, the advantage of this circuit is that different frequencies can be transmitted simultaneously. In the first embodiment, since LRZn (n = 1, 2, 3) is switched by the switch 1 (symbol 3), even when the signal of the frequency f3 is used when the signal of the frequency f1 is used, the frequency Although the distortion characteristic of the signal of f3 does not improve (both the signal of frequency f1 and the signal of frequency f3 pass through the path of the linearizer LRZ1 switched by the switch), in the second embodiment, the linearizer LRZn is used by the filter 1 (reference numeral 13). Since the signal that enters (n = 1, 2, 3) can be naturally separated, even if the signal of frequency f3 is input when the signal of frequency f1 is used, it passes through filters 13a and 13c, respectively. Since the signals are input to the corresponding linearizers LRZ1 and LRZ3, the distortion characteristics can be improved for both signals of two frequencies.

  Also in the second embodiment, switching of the bias voltage of each linearizer and gain adjustment of the variable gain amplifier are controlled by a control circuit (not shown) using a table prepared in advance. . Thereby, highly accurate control can be realized while suppressing the load on the control circuit.

  In the second embodiment, as shown in FIG. 10, the variable gain amplifier 2 is arranged after the filter 2 (reference numeral 14) of the distortion compensation circuit unit 1 and before the broadband amplifier 10. However, the present invention is not limited to this, and a plurality of variable gain amplifiers 2 may be arranged at the subsequent stage (n = 1, 2, 3) of the linearizer LRZn and before the filter 2 (reference numeral 14). With such a configuration, when two or more signals are subjected to distortion compensation, an effect of improving distortion characteristics can be further obtained.

  As described above, in the second embodiment, the same effect as in the first embodiment described above can be obtained, and in the second embodiment, only a plurality of signals having different predetermined frequency bands are allowed to pass. Since the signal path is automatically changed according to the frequency used, the number of points to be controlled is reduced as compared with the case of switching with a switch, and there is an advantage that the load on the control circuit is reduced. . Further, since the signal path is automatically switched depending on whether or not the signal can pass through the filter without being switched by the switch, the distortion characteristics of the signals of two or three frequencies can be improved at the same time.

  In the description of the second embodiment, three types of filters, LPF, BPF, and HPF, are used as the filters in the filters 1 and 2 (reference numerals 13 and 14). All may be BPF. However, even in this case, the frequency of the signal that passes is set to be different from each other in each filter.

Embodiment 3 FIG.
FIG. 12 is a diagram showing an example of the configuration of a distortion compensation circuit device according to Embodiment 3 of the present invention. The distortion compensation circuit device according to the third embodiment has a configuration in which the distortion compensation circuit unit 1 is placed in front of the broadband amplifier 10 as shown in FIG. The distortion compensation circuit according to the third embodiment includes a distortion compensation circuit unit 1 and a variable gain amplifier 2. Also, as shown in FIG. 12A, in the third embodiment, the distortion compensation circuit unit 1 includes three linearizers LRZ1, LRZ2, and LRZ3 connected in series. Each linearizer LRZ1, LRZ2, LRZ3 is provided corresponding to the frequencies f1, f2, f3, respectively. In the third embodiment, specifically, linearizers LRZ1, LRZ2, and LRZ3 shown in FIG. 12B are used as linearizers corresponding to the frequencies f1 to f3, respectively. In the third embodiment, as shown in FIG. 12B, in the linearizers LRZ1 and LRZ2, switches S1 and S2 are provided in parallel, respectively. The switches S1 and S2 are controlled to be opened and closed by a control circuit (not shown). Since other configurations are the same as those of the first and second embodiments, the description thereof is omitted here.

  When the switch S1 is OFF, the linearizer LRZ1 operates. When the switch S1 is ON and the bias voltage applied to the linearizer LRZ1 is negative, the linearizer LRZ1 does not operate. Similarly, when the switch S2 is OFF, the linearizer LRZ2 operates. When the switch S2 is ON and the bias voltage applied to the linearizer LRZ2 is negative, the linearizer LRZ2 does not operate. When both the switches S1 and S2 are ON and the bias voltages of the linearizers LRZ1 and LRZ2 are both negative, the linearizers LRZ1 and LRZ2 do not operate and only the linearizer LRZ3 operates.

Therefore, when it is necessary to operate only the linearizer LRZ1, the switch S1 is turned off under the control of the control circuit, the bias voltage of the linearizer LRZ1 is made positive, the switch S2 is turned on, and the linearizer LRZ2, The bias voltage of LRZ3 is kept negative.
Similarly, when it is necessary to operate only the linearizer LRZ2, the switch S2 is turned OFF, the bias voltage of the linearizer LRZ2 is made positive, the switch S1 is turned ON, and the linearizer LRZ1 is controlled by the control circuit. , LRZ3 has a negative bias voltage.
Similarly, when it is necessary to operate only the linearizer LRZ3, the switch S1 and the switch S2 are both turned ON and the bias voltage of the linearizers LRZ1 and LRZ2 is made negative under the control of the control circuit. The bias voltage of LRZ3 is made positive.

  Next, the operation of the distortion compensation circuit device according to the third embodiment will be briefly described. The signal input to the distortion compensation circuit unit 1 causes reverse distortion of the distortion of the broadband amplifier 10 in any one of the linearizers LRZ1, LRZ2, and LRZ3 switched according to the use frequency of the signal. The signal is input to the variable gain amplifier 2. The signal input to the variable gain amplifier 2 is adjusted in gain in order to efficiently cancel the reverse distortion generated in the distortion compensation circuit unit 1 and the distortion generated in the wideband amplifier 10, and an appropriate signal output is obtained. Adjusted. The signal adjusted to an appropriate output is input to the broadband amplifier 10, and the distortion generated in the broadband amplifier 10 is canceled by the inverse distortion generated by the linearizer, so that the distortion characteristics can be reduced.

  Here, the case where the broadband amplifier 10 has the characteristics shown in FIG. 1 will be described in detail below. As described in the first embodiment, the distortion characteristics of all frequency bands from the frequency f1 to the frequency f3 of the wideband amplifier 10 can be satisfied by switching the linearizer and adjusting the bias voltage of each linearizer. . A case where a signal of frequency f1 is input will be described. In order to improve the distortion of the signal of frequency f1, it is necessary to operate the linearizer LRZ1. Therefore, the switch S1 is turned off. LRZ2 is not operated when the frequency is f1. Therefore, the switch S2 is turned on and LRZ2 is skipped. When the bias voltage of LRZ2 is made positive, the signal passes through LRZ2, so the bias voltage of LRZ2 is made negative. The LRZ3 is not operated when the frequency is f1. Therefore, the bias voltage of LRZ3 is set negative. By doing the same, it becomes possible to improve the distortion both at the frequency f2 and at the frequency f3.

  In the third embodiment, the switches 1 and 2 are switched, the bias voltage is switched, and the gain of the variable gain amplifier is adjusted using a table prepared in advance. Thereby, highly accurate control can be realized while suppressing the load on the control circuit.

  In the above description, only one linearizer is operated as an example. However, the present invention is not limited to this, and two or three linearizers LRZ1, LRZ2, LRZ3 are operated in this configuration. Thus, it is possible to improve the distortion with higher accuracy.

  As described above, in the third embodiment, the distortion compensation circuit for two or more different frequency bands can be used in the front stage of the wideband amplifier (or narrowband amplifier) so that it can cope with a plurality of frequency bands. Since the above-described plurality of linearizers are provided, and these linearizers are connected in series, and based on the frequency band of the input signal, which linearizer is used is switched by the switches S1 and S2. Band distortion can be compensated. In addition to switching the linearizer, the bias voltage applied to the diode provided in the linearizer is also adjusted, so that a wider frequency band can be compensated, and only in each frequency band. In addition, it is possible to obtain an effect that the frequency bands between the respective frequency bands can be used for communication purposes. Further, since the variable gain amplifier 2 is provided in the subsequent stage of the distortion compensation circuit unit 1 to adjust the gain to an appropriate signal output and then input to the wideband amplifier 10, the inverse generated by the linearizer Due to the distortion, the distortion generated in the broadband amplifier 10 can be canceled out efficiently, and the distortion characteristics of the signal output from the broadband amplifier 10 can be reduced. Furthermore, switching of switches 1 and 2, switching of the bias voltage, and gain adjustment of the variable gain amplifier are performed using a table prepared in advance, so high-precision control can be performed while suppressing the load on the control circuit. Can be realized. Furthermore, in the third embodiment, by operating two or three linearizers LRZ1, LRZ2, and LRZ3 at the same time, it is possible to improve the distortion characteristics of both signals of two or three frequencies.

  DESCRIPTION OF SYMBOLS 1 Distortion compensation circuit part, 1a, 1b, 1c, 2a, 2b, 2c, 3a, 3b, 3c Frequency band, 2 gain variable amplifier, 3 switch 1, 4 switch 2, 5 linearizer bank, 10 broadband amplifier, 13 filter 1 , 14 Filter 2, 13a, 13b, 13c, 14a, 14b, 14c Filter, f1, f2, f3 frequency, LRZ1, LRZ2, LRZ3 linearizer, S1, S2 switch.

Claims (4)

A distortion compensation circuit device connected to a preceding stage of an amplifier for compensating for distortion of an output signal of the amplifier,
A distortion compensation circuit for receiving an input signal and generating an inverse distortion for the input signal to cancel the distortion generated in the amplifier;
A plurality of the distortion compensation circuits are arranged in parallel corresponding to different frequency bands,
These distortion compensation circuits are switched and used in accordance with the frequency value of the input signal. A switch is provided in front of the plurality of distortion compensation circuits,
The distortion compensation circuit device according to claim 1, wherein an input signal to the distortion compensation circuit is switched using the switch. A plurality of filters are provided in front of the plurality of distortion compensation circuits,
The filter passes only signals in different frequency bands, and
2. The distortion compensation circuit device according to claim 1, wherein switching of an input signal to the distortion compensation circuit is performed using the filter. A distortion compensation circuit device connected to a preceding stage of an amplifier for compensating for distortion of an output signal of the amplifier,
A distortion compensation circuit for receiving an input signal and generating an inverse distortion for the input signal to cancel the distortion generated in the amplifier;
A plurality of the distortion compensation circuits are arranged in series corresponding to different frequency bands,
A switch is connected in parallel to at least one of the distortion compensation circuits;
The distortion compensation circuit device, wherein the distortion compensation circuit is switched by the switch according to the frequency value of the input signal.

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