JP2000353923A - Feedforward amplifier having double loop - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve highly efficient amplification and stable distortion compensation. SOLUTION: A distortion injection path is obtained as the feedforward constitution of a distortion detecting circuit 7 for an auxiliary amplifier and a distortion removing circuit 74 for an auxiliary amplifier, and a variable attenuator 49 and a variable phase shifter 51 are inserted into the linear signal transmission path of the distortion detecting circuit 73, and a second pilot signal injected into the stage of a main amplifier 23 is detected by the distortion detecting circuit 74, and the attenuator 49 and the phase shifter 51 are controlled so that the level can be minimized. The second pilot signal is detected from an output path, and a variable attenuator 27 and a variable phase shifter 28 of the input path of a first auxiliary amplifier 29 are controlled so that the level can be minimized, and an attenuator 49 and a phase shifter 51 are linked only by the controlled variable.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a feed-forward amplifier which is a linear amplifier mainly used in a high frequency band, and more particularly to a power forward amplifier having high power efficiency.

[0002]

2. Description of the Related Art FIG. 5 shows a configuration of a feedforward amplifier. The feedforward amplifier includes a distortion detection circuit 13 including an amplification transmission path 11 and a linear signal transmission path 12 of the main amplifier, a main signal transmission path 14 and a distortion injection path 1.
5 comprises a distortion removal circuit 16.
The main amplifier amplification transmission path 11 includes a variable attenuator 21, a variable phase shifter 22, and a main amplifier 23 connected in series.
The linear signal transmission path 12 includes a delay line 24 and a phase inversion circuit 2.
5 in series. Main signal transmission path 14
Is constituted by a delay line 26. The distortion injection path 15 is configured by connecting a variable attenuator 27, a variable phase shifter 28, and an auxiliary amplifier 29 in series. The input of the feedforward amplifier is distributed by the power distribution circuit 31 to the amplification transmission path 11 and the linear signal transmission path 12 of the main amplifier. The distortion detecting circuit 13 and the distortion removing circuit 16 are cascaded by the power combiner / distributor 32. The output of the feedforward amplifier is obtained from a power combiner 33 that combines the outputs of the main signal transmission path 14 and the distortion injection path 15.

The feed-forward amplifier detects a distortion component generated by the main amplifier 23 in a distortion detection circuit 13 at a preceding stage, and adjusts a phase amount and an amplitude amount of the distortion component generated from the main amplifier 23 by a distortion removal circuit 16 at a subsequent stage. Then, the nonlinear distortion generated by the main amplifier 23 is removed by injecting it into the output signal of the main amplifier 23. In general, the amount of improvement in the nonlinear distortion of the feedforward amplifier depends on the adjustment of the variable attenuator 21 and the variable phase shifter 22 of the distortion detection circuit 13 and the variable attenuator 27, the variable phase shifter 28, and the auxiliary amplifier 29 of the distortion removal circuit 16. .
The accuracy of the adjustment and the like is shown in Japanese Patent Application No. 63-23574 "Automatic Adjustment Circuit of Feedforward Amplifier".
For example, the phase and amplitude deviations for obtaining a distortion compression amount of 30 dB or more are within ± 2 degrees and ± 0.3 dB, respectively, and the balance and adjustment of the transmission characteristics of the distortion detection circuit 13 and the distortion removal circuit 16 are adjusted. It can be said that strict conditions are required for completeness.

What compensates for distortion by the feedforward amplifier is the nonlinear distortion of the main amplifier 23. Therefore, the nonlinear distortion generated in the auxiliary amplifier 29 cannot be compensated for by the feedforward amplifier in principle in terms of the circuit configuration. In addition, since the balance conditions of the two paths are severe, the auxiliary amplifier 29 of the conventional feedforward amplifier is required to have linearity. Generally, in order to enhance the linearity of an amplifier circuit using a semiconductor amplifying element, an operating condition of so-called class A bias is used, and the saturation output is sufficiently higher than the peak power of the signal to be amplified.

[0005]

In recent years, there has been a demand for miniaturization, economy, and low power consumption of wireless devices. The same applies to a wireless device using a feedforward amplifier. In order to reduce the power consumption of the feedforward amplifier, it is essential to increase the efficiency of the main amplifier and the auxiliary amplifier. As a result, it is possible to reduce the size of the heat radiation plate of the amplifier, and as a result, it is possible to achieve a reduction in the size of the wireless device.

The efficiency of the main amplifier can be increased by a push-pull circuit or the like under a class B bias condition. Non-linear distortion caused by the main amplifier can be compensated for by a conventional feed-forward amplifier. On the other hand, increasing the power efficiency of the auxiliary amplifier 29 inserted into the distortion injection path 15 of the feedforward amplifier generally requires operating the semiconductor amplifier element of the auxiliary amplifier under a bias condition such as class B or class C. is there. Nonlinear distortion caused by these bias conditions cannot be compensated in principle by feedforward amplification as described above. Therefore, increasing the efficiency of the auxiliary amplifier 29 has a problem that the distortion compensation capability of the feedforward amplifier is reduced.

For example, in the literature (Toshio Nojima, Shoichi Narahashi,
"Ultra Low Distortion Multi-Frequency Common Amplifier for Mobile Communication", IEICE Technical Report, RCS90-
4, 1990), the saturation output of the main amplifier is set to 100
W, the saturation output of the auxiliary amplifier is 1 /
In the case of a GaAs MESFET as a semiconductor amplifier element of the main amplifier and the auxiliary amplifier in the 8, 1.5 GHz band, the drain voltage of the MESFET of the main amplifier is 12 V, the drain current is 20 A, and the drain voltage of the MESFET of the auxiliary amplifier is 1
The power supplied to the feedforward amplifier was 153 under the condition of a class A bias and 2 V and a drain current of 5 A.
It is about W, and the drain efficiency is about 5% or less. High efficiency amplifier circuit such as class B push-pull for main amplifier and class A amplifier circuit for auxiliary amplifier at most about 10%
Only the following drain efficiency can be obtained.

The distortion detecting circuit and the distortion removing circuit need to control the variable attenuator and the variable phase shifter of each loop so as to have equal amplitude, equal delay, and opposite phase. Generally, the amount of nonlinear distortion improvement of the feedforward amplifier depends on the balance of the loop by adjusting the variable attenuator and the variable phase shifter. The accuracy of the adjustment and the like is shown in Japanese Patent Application No. 63-23574 "Automatic Adjustment Circuit of Feedforward Amplifier". For example, the phase and amplitude deviations for obtaining a distortion compression amount of 30 dB or more are within ± 2 degrees and ± 0.3 dB, respectively.
B, which means that strict conditions are required for the balance of the transmission characteristics of the distortion detection circuit and the distortion removal circuit and the completeness of the adjustment. In practice, it is not easy to completely maintain the balance between the distortion detection circuit and the distortion removal circuit. Also, even if the initial settings are complete,
Since the characteristics of the amplifier change due to changes in the ambient temperature, the power supply, and the like, it is extremely difficult to stably maintain good balance over time.

An automatic adjustment method using a pilot signal has been known as a method for maintaining the perfect balance of the distortion detection circuit and the distortion removal circuit of the feedforward amplifier with high accuracy. For example, there is Japanese Patent Application No. 63-23574.
Toshio Nojima, Shoichi Narahashi,
"Ultra-low distortion multi-frequency common amplifier for mobile communication ... Self-adjustable feedforward amplifier (SAFF-A) ...", IEICE, RCS90-
4, 1990 are known.

Each of these automatic adjustment methods is applied to a feedforward amplifier for removing a nonlinear distortion component generated by a conventional main amplifier. Until now, there has been no automatic adjustment method using a pilot signal applicable to a feedforward amplifier capable of high-efficiency amplification in which a distortion injection path is formed in a feedforward configuration. The problem to be solved by the present invention is to provide a feedforward amplifier having a distortion compensation capability equal to or higher than that of a conventional feedforward amplifier and enabling automatic adjustment of each loop of a feedforward amplifier capable of high-efficiency amplification. It is in.

[0011]

According to the present invention, the strain injection path is constituted by a feedforward amplifier. Specifically, the auxiliary amplifier is regarded as a main amplifier, and a distortion injection path is configured using a first auxiliary amplifier distortion detection circuit and a first auxiliary amplifier distortion removal circuit for the auxiliary amplifier (first auxiliary amplifier), Non-linear distortion generated in the auxiliary amplifier (first auxiliary amplifier) is compensated by this feed-forward configuration of the distortion injection path. Further, the auxiliary amplifier (first auxiliary amplifier) can be operated with high efficiency by class B, class C, class E, class F other than class A bias.

Further, as will be described below, each of the claims is configured to automatically balance each loop. (1) According to the first aspect of the present invention, the path constituted by the delay line and the phase inversion circuit of the distortion detection circuit for the first auxiliary amplifier is constituted by the variable attenuator and the variable phase shifter, and the main amplifier is used as the main amplifier. The pilot signal to be injected is detected by the first auxiliary amplifier distortion removal path, and the controller controls the variable attenuator and the variable phase shifter so as to minimize the detection level. The balance of the loop of the distortion detection circuit and the distortion removal circuit for the first auxiliary amplifier is achieved, and the balance of the loop of the distortion removal circuit is changed to the main amplifier using the variable attenuator and variable phase shifter on the input side of the first auxiliary amplifier. The injected pilot signal is detected at the output of the feedforward amplifier, and is controlled by a controller so as to minimize the detection level. The newly inserted variable attenuator and variable phase shifter adjust the set values in conjunction with the attenuation amount and the phase amount controlled at this time. Thereby, the balance of the distortion removal circuit and the distortion detection circuit for the first auxiliary amplifier can be achieved at the same time.

(2) According to the second aspect of the present invention, the path constituted by the delay line and the phase inversion circuit of the first auxiliary amplifier distortion detection circuit is constituted by a variable attenuator and a variable phase shifter,
The pilot signal injected into the input end of the distortion injection path is detected by the first auxiliary amplifier distortion removal path, and the controller controls the variable attenuator and the variable phase shifter to minimize the detection level. I do. Achieved the balance of the loop of the distortion detection circuit and the distortion removal circuit for the first auxiliary amplifier, and injected the variable attenuator and variable phase shifter on the input side of the first auxiliary amplifier into the main amplifier. The detected pilot signal is detected at the output of the feedforward amplifier, and is controlled by a controller so as to minimize the detection level. The newly inserted variable attenuator and variable phase shifter adjust the set values in conjunction with the attenuation amount and the phase amount controlled at this time. Thereby, the balance of the distortion removal circuit and the distortion detection circuit for the first auxiliary amplifier can be achieved at the same time.

(3) According to the third aspect of the present invention, the second variable phase shifter and the second variable attenuator are inserted before the power divider at the input of the first auxiliary amplifier distortion detecting circuit. A delay line is used for the signal transmission path for the first auxiliary amplifier of the distortion detection circuit for the first auxiliary amplifier, and a fourth variable phase shifter, a fourth variable attenuator, and a phase inversion circuit are used for the linear signal transmission path for the first auxiliary amplifier. To constitute a first auxiliary amplifier distortion detection circuit. In the invention of claim 1, the cooperative operation of the second controller and the fourth controller is required, but in the invention of claim 3, this cooperative operation is not required. Balancing of the four loops of the feedforward amplifier can be achieved independently.

(4) According to the invention of claim 4, the second variable phase shifter and the second variable attenuator are inserted in front of the power divider at the input of the distortion detection circuit for the first auxiliary amplifier. A delay line is used for the signal transmission path for the first auxiliary amplifier of the distortion detection circuit for the first auxiliary amplifier, and a fourth variable phase shifter, a fourth variable attenuator, and a phase inversion circuit are used for the linear signal transmission path for the first auxiliary amplifier. To constitute a first auxiliary amplifier distortion detection circuit. According to the second aspect of the present invention, the cooperative operation of the second controller and the fourth controller is required, but the fourth aspect of the present invention does not require this cooperative operation. Balancing of the four loops of the feedforward amplifier can be achieved independently. According to the present invention, the efficiency of the auxiliary amplifier can be increased by forming the distortion injection path in a feedforward configuration, and the distortion component generated due to the increased efficiency can be removed. Further, the balance of the four loops existing by the feed-forward configuration of the distortion injection path is controlled by controlling the variable attenuator and the variable phase shifter of each loop so as to minimize the level using the pilot signal. It is possible to compensate for the distortion component generated by the main amplifier and the distortion component generated by the first auxiliary amplifier, and to apply the operating conditions of the high efficiency amplification other than the class A bias condition to the semiconductor amplification element of the first auxiliary amplifier. .

[0016]

FIG. 1 shows a first embodiment of the present invention. FIG. 1 uses three pilot signals and four control means. The feedforward amplifier of the present invention includes a first pilot signal generator 41 on the amplifier input side,
A directional coupler 42 for injecting a first pilot signal into an amplifier input; a power splitter 31 for splitting the amplifier input signal into two paths; a first variable attenuator 21 and a first variable attenuator 21 for receiving the split signal; A path 11 composed of a phase shifter 22 and a main amplifier 23, a path 12 composed of a delay line 24 and a phase inverting circuit 25, a second pilot signal generator 43 injected between stages of the main amplifier 23, The power combining of the two paths 11 and 12 and the power combining / distributing into two paths /
A divider 32, a delay line 26 for inputting a signal distributed by the power combiner / divider 32, and a directional coupler 44 for inputting the distributed signal and extracting a first pilot signal
And a first pilot signal detector 45 for detecting the extracted first pilot signal, and a first variable attenuator 21 for inputting the detected level and minimizing the level.
And a first controller 46 for controlling the first variable phase shifter 22, an output of the directional coupler 44 from which the first pilot signal is extracted, and a power divider 47 for dividing the output into two paths, A path 48 constituted by the second variable attenuator 27, the second variable phase shifter 28, and the first auxiliary amplifier 29
And a path 53 including a fourth variable attenuator 49, a fourth variable phase shifter 51, and a phase inverting circuit 52 for inputting the distributed signal, and a third pilot signal between the stages of the first auxiliary amplifier 29. Injecting means and third pilot signal generator 54
And a power combiner / divider 55 that combines the power of these two paths 48 and 53 and distributes the two signals into two paths, a path 60 including a delay line 56 that inputs the distributed signal, and inputs the distributed signal. A directional coupler 57 for extracting the second pilot signal, a second pilot signal detector 58 for detecting the level of the extracted second pilot signal, and a fourth variable attenuation so as to minimize the detected level Controller 49 for controlling the device 49 and the fourth variable phase shifter 51, and a third variable attenuator 61, a third variable phase shifter 62, and a second auxiliary amplifier 63 for receiving the output of the directional coupler 57. Path 64, a power combiner 65 that combines the outputs of these two paths 60, 64, and a directional coupler 66 that receives the output of the power combiner 65 and extracts the third pilot signal.
And a third pilot signal detector 67 that receives the extracted third pilot signal and detects its level, and a third variable attenuator 61 that minimizes the detected level.
And a third controller 68 for controlling the third variable phase shifter 62, a power combiner 33 for power combining the output of the path 14 by the delay line 26 and the output of the directional coupler 66 for extracting the third pilot signal. A directional coupler 69 that receives the power-combined signal and extracts a second pilot signal, a second pilot signal detector 71 that detects the level of the extracted second pilot signal, and that the detected level is A second controller 72 for controlling the second variable attenuator 27 and the second variable phase shifter 28 so as to minimize it is provided.

Second variable attenuator 27, second variable phase shifter 2
8. A first auxiliary amplifier distortion detection circuit 7 is provided by a path 48 including the first auxiliary amplifier 29 and a path 53 including the fourth variable attenuator 49, the fourth variable phase shifter 51, and the phase inverting circuit 52.
The first auxiliary amplifier distortion detection circuit 73 detects a distortion component generated in the first auxiliary amplifier 29.
The path 60 of the delay line 56, the path 64 including the third variable attenuator 61, the third variable phase shifter 62, and the second auxiliary amplifier 63 and the first auxiliary amplifier distortion removal circuit 74 are configured. The distortion component detected by the distortion detection circuit 73 is injected into the output of the first auxiliary amplifier 29 with opposite phase, equal amplitude, and equal delay, and the distortion component generated by the first auxiliary amplifier 29 is removed.

As described above, the feedforward configuration of the strain injection path 15 allows the first auxiliary amplifier 29 to operate the semiconductor amplifying element of the first auxiliary amplifier 29 with high efficiency under operating conditions other than the class A bias. The distortion component newly generated from the auxiliary amplifier 29 based on the conversion is detected by the auxiliary amplifier distortion detection circuit 73, and the detected distortion component is used by the auxiliary amplifier distortion removal circuit 74 during the amplification output of the first auxiliary amplifier 29. Of the first auxiliary amplifier 29 is removed.
Therefore, highly efficient amplification of the first auxiliary amplifier 29 can be achieved.

As described above, the delay line 2 of the distortion removing circuit 16
6, a loop composed of a path composed of the second variable attenuator 27, the second variable phase shifter 28, the first auxiliary amplifier 29, and the delay line 56, and a loop of the distortion detection circuit 73 for the first auxiliary amplifier. Are independently provided in the first auxiliary amplifier distortion detection circuit 73, the fourth variable attenuator 49 and the fourth variable phase shifter 51 are newly provided.

The feedforward amplifier according to the present invention uses three pilot signals to generate a distortion detection circuit 13,
The first auxiliary amplifier distortion detection circuit 73, the first auxiliary amplifier distortion removal circuit 74, and the distortion removal circuit 16 are balanced. At this time, as described above, the balance of the loop of the first auxiliary amplifier distortion detection circuit 73 is achieved by the fourth variable attenuator 49 and the fourth variable phase shifter 51 using the second pilot signal. . After the balance of the loop of the distortion removal circuit 16 is achieved, the second variable attenuator 27 and the second variable phase shifter 28 are connected using the second pilot signal after achieving the loop balance of the first auxiliary amplifier distortion detection circuit 73. To achieve. At this time, the setting values of the second variable attenuator 27 and the second variable phase shifter 28 on the path 48 of the first auxiliary amplifier 29 are changed after achieving the loop balance of the first auxiliary amplifier distortion detection circuit 73. , The set values of the fourth variable attenuator 49 and the fourth variable phase shifter 51 are corrected in conjunction with the set values of the second variable attenuator 27 and the second variable phase shifter 28, respectively. By this series of interlocking and correcting process of the set values, the balance of each loop of the distortion removing circuit 16 and the first auxiliary amplifier distortion detecting circuit 73 is achieved.

FIG. 2 shows a second embodiment of the present invention. FIG. 2 uses four pilot signals and four control means. In FIG. 2, parts corresponding to those in FIG. 1 are given the same numbers. In this embodiment, the output of the directional coupler 44 from which the first pilot signal is extracted is input to the directional coupler 81, and the fourth pilot signal from the fourth pilot signal generator 82 is injected into the directional coupler 81. , The output of the directional coupler 81 is input to the power divider 47. The fourth pilot signal is extracted from the output of the directional coupler 57 by the fourth pilot signal detector 83, and the level of the fourth pilot signal is detected. The fourth controller 59 controls the fourth variable attenuator 49 and the fourth variable phase shifter 51 so as to minimize the level of the detected fourth pilot signal. Other configurations are the same as those in FIG.

As described above, the delay line 2 of the distortion removal circuit 16
6, a loop composed of a path composed of the second variable attenuator 27, the second variable phase shifter 28, the first auxiliary amplifier 29, and the delay line 56, and a loop of the distortion detection circuit 73 for the first auxiliary amplifier. In order to achieve independently, the first auxiliary amplifier distortion detection circuit 73 has a fourth variable attenuator 49 and a fourth variable phase shifter 51, and the input side of the first auxiliary amplifier distortion detection circuit 73 has a fourth pilot signal. A generator 82 and a directional coupler 81 as an injection means are newly provided.

The feedforward amplifier according to this embodiment uses four pilot signals to generate a distortion detection circuit 1
3. The respective balances of the first auxiliary amplifier distortion detecting circuit 73, the first auxiliary amplifier distortion removing circuit 74, and the distortion removing circuit 16 are achieved. At this time, as described above, the balance of the loop of the first auxiliary amplifier distortion detection circuit 73 is achieved by the fourth variable attenuator 49 and the fourth variable phase shifter 51 using the fourth pilot signal. . After the balance of the loop of the distortion removal circuit 16 is achieved, the second variable attenuator 27 and the second variable phase shifter 28 are connected using the second pilot signal after achieving the loop balance of the first auxiliary amplifier distortion detection circuit 73. To achieve. At this time, the second variable attenuator 27 on the path of the first auxiliary amplifier 29
In order to change the set values of the second and third variable phase shifters 28 after achieving the loop balance of the first auxiliary amplifier distortion detection circuit 73, the set values of the fourth variable attenuator 49 and the fourth variable phase shifter 51 are changed to the second The correction is made in conjunction with the set values of the variable attenuator 27 and the second variable phase shifter 28. By this series of interlocking and correcting process of the set values, the distortion removing circuit 16 and the distortion detecting circuit 73 for the first auxiliary amplifier are used.
Achieve the equilibrium of each loop.

FIG. 3 shows a third embodiment of the present invention, in which parts corresponding to those in FIG. 1 are denoted by the same reference numerals. FIG. 3 uses three pilot signals and four control means. In the feedforward amplifier of this embodiment, the output of the directional coupler 44 from which the first pilot signal has been extracted is input not to the power divider 47 but to the series circuit of the second variable attenuator 27 and the second variable phase shifter 28, The output of this series circuit is input to a power divider 47, where one of the divided signals is divided into a path constituted by the delay line 85 and the first auxiliary amplifier 29, and the other divided signal is Fourth variable attenuator 49, fourth variable phase shifter 51, and phase inverting circuit 52
Is input to each of the routes composed of. The outputs of these two paths are supplied to a power combiner / divider 55. Others are the same as FIG.

As described above, the delay line 2 of the distortion removal circuit 16
6, the second variable attenuator 27, the second variable phase shifter 28, the delay line 85, the first auxiliary amplifier 29, and the delay line 5
6 and the loop of the first auxiliary amplifier distortion detecting circuit 73 are independently achieved, so that the second variable phase shifter 27 and the second variable phase shifter 27 are connected to the input of the first auxiliary amplifier distortion detecting circuit 73. A second variable attenuator 28 is provided, and a fourth variable attenuator 49 and a fourth variable phase shifter
1 is provided.

The feedforward amplifier according to this embodiment uses three pilot signals to generate a distortion detection circuit 1
3. The respective balances of the first auxiliary amplifier distortion detecting circuit 73, the first auxiliary amplifier distortion removing circuit 74, and the distortion removing circuit 16 are achieved. At this time, the balance of the loop of the first auxiliary amplifier distortion detection circuit 73 is achieved by the fourth variable attenuator 49 and the fourth variable phase shifter 51 using the second pilot signal. The balance of the loop of the distortion removing circuit 16 is achieved by using the second variable attenuator 27 and the second variable phase shifter 28 using the second pilot signal. Since neither the variable phase shifter nor the variable attenuator, which is the loop adjusting means, is shared, the loop balance of the first auxiliary amplifier distortion detection circuit 73 and the loop balance of the distortion removal circuit 16 can be achieved independently. In this way, the respective loops of the distortion removal circuit 16 and the first auxiliary amplifier distortion detection circuit 73 are balanced by providing a loop adjusting means of the distortion removal circuit 16 before the first auxiliary amplifier distortion detection circuit 73. The first auxiliary amplifier distortion detection circuit 73 can be independently achieved by providing the loop adjustment means of the first auxiliary amplifier distortion detection circuit 73.

FIG. 4 shows a fourth embodiment of the present invention, in which parts corresponding to those in FIG. 3 are denoted by the same reference numerals. FIG.
Uses four pilot signals and four control means. In this embodiment, the second variable phase shifter 28 and the power divider 4
7, a directional coupler 81 is inserted, and the fourth pilot signal from the fourth pilot signal generator 82 is injected into the directional coupler 81. A fourth pilot signal is detected by the fourth pilot signal detector 83 from the output of the directional coupler 57, the level thereof is detected, and the fourth variable attenuator 49 and the fourth variable attenuator 49 are set so as to minimize the detected level. The variable phase shifter 51 is controlled by the fourth controller 59. Others are the same as FIG.

As described above, the delay line 2 of the distortion removal circuit 16
6, the second variable attenuator 27, the second variable phase shifter 28, the delay line 85, the first auxiliary amplifier 29, and the delay line 5
6 and the loop of the first auxiliary amplifier distortion detecting circuit 73 are independently achieved, so that the second variable phase shifter 27 and the second variable phase shifter 27 are connected to the input of the first auxiliary amplifier distortion detecting circuit 73. A second variable attenuator 28 is provided, and a fourth variable attenuator 49 and a fourth variable phase shifter
1 and a fourth pilot signal generator 82 and a directional coupler 81 as injection means are newly provided on the input side of the distortion detection circuit 73 for the first auxiliary amplifier.

The feedforward amplifier according to this embodiment uses four pilot signals to generate a distortion detection circuit 1
3. The respective balances of the first auxiliary amplifier distortion detecting circuit 73, the first auxiliary amplifier distortion removing circuit 74, and the distortion removing circuit 16 are achieved. At this time, the balance of the loop of the first auxiliary amplifier distortion detection circuit 73 is achieved by the fourth variable attenuator 49 and the fourth variable phase shifter 51 using the fourth pilot signal. The balance of the loop of the distortion removing circuit 16 is achieved by using the second variable attenuator 27 and the second variable phase shifter 28 using the second pilot signal. Since neither the variable phase shifter nor the variable attenuator, which is the loop adjusting means, is shared, the loop balance of the first auxiliary amplifier distortion detection circuit 73 and the loop balance of the distortion removal circuit 16 can be achieved independently. In this way, the respective loops of the distortion removal circuit 16 and the first auxiliary amplifier distortion detection circuit 73 are balanced by providing a distortion removal loop adjusting means before the first auxiliary amplifier distortion detection circuit 73. This can be achieved independently by providing the means for adjusting the loop of the distortion detecting circuit 73 for one auxiliary amplifier in the distortion detecting circuit 73 for the first auxiliary amplifier. The first to fourth controllers in each of the above embodiments can share a control algorithm in minimizing the level detected from each pilot signal, so that the control of each variable attenuator and each variable phase shifter is performed in a time-sharing manner. May be implemented by a single controller. This allows a common controller to be used,
The power consumption of the controller can be reduced. As the control algorithm, an adaptive algorithm, such as a perturbation method or a least squares estimation, which has been put to practical use can be applied. Generally, the balance of the loop of the feedforward amplifier fluctuates due to fluctuations in the power supply voltage, changes in the temperature of the device, and the like. The rate of change is relatively slow. Therefore, even a control algorithm that takes time to converge to the optimum value can sufficiently cope with the control of the feedforward amplifier having the double loop of the present invention.

Each pilot signal is set to a non-modulated wave set to a different frequency or a signal obtained by modulating a carrier having the same frequency by a different modulated wave.
Alternatively, any one of spread modulation of the same carrier by different spread codes may be used. A pilot signal detector that detects a pilot signal using an unmodulated wave is configured by a narrow-band level detector. For example, the configuration is such that the output is limited by a band-pass filter, and the output of the filter is detected by a level detector such as a diode. A pilot signal detector that detects a pilot signal using a modulated wave includes a frequency converter that frequency-converts a pilot signal band into a baseband band, and a demodulator that demodulates the frequency-converted baseband signal. Since the pilot signal of the modulated wave demodulates the pilot signal compared to the pilot signal of the unmodulated wave, equalization processing and error correction processing for various kinds of interference and noise can be applied. Therefore, the balance of each loop can be achieved with less pilot signal power. A pilot signal detector that detects a pilot signal using a spreading code is a frequency converter that frequency-converts the pilot signal band into a baseband band, and a despreader that despreads the frequency-converted baseband signal, The demodulator demodulates the signal. Thus, the automatic adjustment device for a feedforward amplifier according to the present invention can be applied to various pilot signals.

[0031]

According to the present invention, the following effects can be obtained. (1) To provide an automatic adjustment device for a feedforward amplifier having a double loop capable of high-efficiency amplification. (2) Stable distortion compensation capability can be provided. (3) According to (1) and (2), low power consumption of the feedforward amplifier is achieved, and a compact device and an economical device are provided.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the first embodiment;

FIG. 2 is a block diagram showing an embodiment according to claim 2;

FIG. 3 is a block diagram showing an embodiment according to claim 3;

FIG. 4 is a block diagram showing an embodiment according to claim 4;

FIG. 5 is a block diagram showing a conventional feedforward amplifier.

[Explanation of symbols]

Reference Signs List 13 distortion detection circuit 51 fourth variable phase shifter 16 distortion removal circuit 52 phase inversion circuit 21 first variable attenuator 61 third variable attenuator 22 first variable phase shifter 62 third variable phase shifter 27 second variable attenuator 63 Two auxiliary amplifier 28 Second variable phase shifter 73 First auxiliary amplifier distortion detection circuit 29 First auxiliary amplifier 74 First auxiliary amplifier distortion removal circuit 49 Fourth variable attenuator 82 Fourth pilot signal generator

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5J090 AA01 AA41 CA21 CA36 FA08 FA20 GN02 GN05 GN07 KA00 KA04 KA15 KA16 KA23 KA68 MA14 MA20 TA01 5J092 AA01 AA41 CA21 CA36 FA08 FA20 KA00 KA04 KA15 KA16 KA01 KA01 QA02 SA01

Claims (4)

[Claims] A distortion detection circuit for detecting nonlinear distortion of a main amplifier, amplifying the detected distortion component using a first auxiliary amplifier, and then injecting the amplified distortion component into an output of the main amplifier to cancel the distortion component. A first auxiliary amplifier distortion detecting circuit for detecting nonlinear distortion of the first auxiliary amplifier of the distortion removing circuit, and a second auxiliary amplifier for detecting a distortion component detected by the first auxiliary amplifier distortion detecting circuit. A first auxiliary amplifier distortion removal circuit for canceling the distortion component of the first auxiliary amplifier by re-injecting it into the output of the first auxiliary amplifier and re-injecting it into the output of the main amplifier. Means for injecting a first pilot signal inserted into an input path of a feedforward amplifier; first electrically variable attenuating means and first electrically variable phase means inserted into an input path of a main amplifier of the distortion detection circuit When, First pilot signal detection means inserted into the input path of the first auxiliary amplifier distortion detection circuit, and an output signal of the first pilot signal detection means,
A first controller for controlling the first electric variable attenuator and the first electric variable phase shifter, a means inserted between main amplifier stages of the distortion detection circuit to inject a second pilot signal, Second electric variable attenuating means and second electric variable phase means inserted into the input path of the first auxiliary amplifier of the first auxiliary amplifier distortion detection circuit, and the second electric variable attenuation means inserted into the output path of the distortion removing circuit. A second pilot signal detecting means, and a second controller which receives an output of the first second pilot signal detecting means and controls the second electric variable attenuator and the second electric variable phase shifter Means for injecting a third pilot signal inserted between the stages of the first auxiliary amplifier, and a third electrically variable inserted in the input path of the second auxiliary amplifier of the first auxiliary amplifier distortion removal circuit Attenuating means and third electrically variable phase means; A third pilot signal detecting means inserted into an output path of the first auxiliary amplifier distortion removing circuit; an output of the third pilot signal detecting means is input to the third electric variable attenuating means; A third controller for controlling a dynamic variable phase means, a fourth electrical variable attenuating means and a fourth electrical variable phase means inserted into a linear signal transmission path of the first auxiliary amplifier distortion detection circuit, A second second pilot signal detecting means inserted into an input path of a second auxiliary amplifier of the first auxiliary amplifier distortion removing circuit; and an output of the second second pilot signal detecting means, And a fourth controller for controlling the fourth electrically variable phase means, and the first electrically variable means so as to minimize the first pilot signal detection level detected by the first pilot signal detection means. Decrease Means and the first electric variable phase means are controlled in a stepwise manner by the first controller, and the fourth pilot signal detecting means detects the second pilot signal detected by the second second pilot detecting means so as to minimize the second pilot signal detection level. The electric variable attenuation means and the fourth electric variable phase means are controlled stepwise by the fourth controller, and the third pilot signal detection level detected by the third pilot signal detection means is minimized. The third electric variable attenuating means and the third electric variable phase means are controlled stepwise by the third controller, and the second pilot signal detection level detected by the first second pilot signal detecting means is minimized. The second electric variable attenuating means and the second electric variable phase means are controlled in a stepwise manner by the second controller, and the second electric variable controlled by the second controller. Damping means and the second And control means for controlling the respective control amounts of the dynamic variable phase means by the fourth controller in conjunction with the fourth electrical variable attenuation means and the fourth electrical variable phase means. Feedforward amplifier with a double loop. 2. A distortion detection circuit for detecting non-linear distortion of a main amplifier, amplifying the detected distortion component using a first auxiliary amplifier, and then injecting the amplified distortion component into an output of the main amplifier to cancel the distortion component. A first auxiliary amplifier distortion detecting circuit for detecting nonlinear distortion of the first auxiliary amplifier of the distortion removing circuit, and a second auxiliary amplifier for detecting a distortion component detected by the first auxiliary amplifier distortion detecting circuit. A first auxiliary amplifier distortion removal circuit for canceling the distortion component of the first auxiliary amplifier by re-injecting it into the output of the first auxiliary amplifier and re-injecting it into the output of the main amplifier. Means inserted into the input path of the feedforward amplifier to inject the first pilot signal; first electric variable attenuation means and first electric variable phase means inserted into the input path of the main amplifier of the distortion detection circuit When A first pilot signal detecting means inserted in the input path of the distortion detection circuit for said first auxiliary amplifier, the output signal of the first pilot signal detecting means inputs,
A first controller for controlling the first electric variable attenuator and the first electric variable phase shifter, a means inserted between main amplifier stages of the distortion detection circuit to inject a second pilot signal, Second electric variable attenuating means and second electric variable phase means inserted into the input path of the first auxiliary amplifier of the first auxiliary amplifier distortion detection circuit, and the second electric variable attenuation means inserted into the output path of the distortion removing circuit. A second pilot signal detecting unit, a second controller for receiving an output of the second pilot signal detecting unit, and controlling the second electric variable attenuator and the second electric variable phase shifter; Means inserted between amplifier stages for injecting a third pilot signal; third electric variable attenuating means inserted into the input path of the second auxiliary amplifier of the first auxiliary amplifier distortion removal circuit; Variable phase means, and the first auxiliary Means for injecting a fourth pilot signal inserted into the input path of the amplifier distortion detection circuit, fourth electric variable attenuating means inserted into the linear signal transmission path of the first auxiliary amplifier distortion detection circuit, and Electrically variable phase means, third pilot signal detection means inserted into the output path of the first auxiliary amplifier distortion removal circuit, and inputting the output of the third pilot signal detection means, Attenuating means and a third controller for controlling the third electrically variable phase means; a fourth pilot signal detecting means inserted into an input path of a second auxiliary amplifier of the first auxiliary amplifier distortion removing circuit; A fourth controller which receives an output of the fourth pilot signal detecting means and controls the fourth electric variable attenuating means and the fourth electric variable phase means, and a first pilot detected by the first pilot signal detecting means. The first electric variable attenuating means and the first electric variable phase means are controlled stepwise by the first controller so as to minimize the reset signal detection level, and are detected by the second pilot detecting means. The second electric variable attenuating means and the second electric variable phase means are controlled stepwise by the second controller so as to minimize the second pilot signal detection level, and the third pilot signal detecting means The third electric variable attenuating means and the third electric variable phase means are controlled stepwise by the third controller so as to minimize the detected third pilot signal detection level, and the fourth pilot signal detection is performed. The fourth electric variable attenuating means and the fourth electric variable phase means are controlled stepwise by the fourth controller so as to minimize the fourth pilot signal detection level detected by the means, and With the controller The controlled amount of each of the controlled second electric variable attenuation means and the second electric variable phase means is controlled by the fourth controller with respect to the fourth electric variable attenuation means and the fourth electric variable phase means. A feed-forward amplifier having a double loop. 3. A distortion detection circuit for detecting non-linear distortion of a main amplifier, amplifying the detected distortion component using a first auxiliary amplifier, and then injecting the amplified distortion component into an output of the main amplifier to cancel the distortion component. A first auxiliary amplifier distortion detecting circuit for detecting nonlinear distortion of the first auxiliary amplifier of the distortion removing circuit, and a second auxiliary amplifier for detecting a distortion component detected by the first auxiliary amplifier distortion detecting circuit. A first auxiliary amplifier distortion removal circuit for canceling the distortion component of the first auxiliary amplifier by re-injecting it into the output of the first auxiliary amplifier and re-injecting it into the output of the main amplifier. Means inserted into the input path of the feedforward amplifier to inject the first pilot signal; first electric variable attenuation means and first electric variable phase means inserted into the input path of the main amplifier of the distortion detection circuit When A first pilot signal detecting means inserted in the input path of the distortion detection circuit for said first auxiliary amplifier, the output signal of the first pilot signal detecting means inputs,
A first controller for controlling the first electric variable attenuator and the first electric variable phase shifter, a means inserted between main amplifier stages of the distortion detection circuit to inject a second pilot signal, A second electric variable attenuating means and a second electric variable phase means inserted in front of the power divider at the input of the first auxiliary amplifier distortion detection circuit, and a second electric variable attenuation means inserted into the output path of the distortion removal circuit. A second pilot signal detecting means, and a second controller which receives an output of the first second pilot signal detecting means and controls the second electric variable attenuator and the second electric variable phase shifter Means for injecting a third pilot signal inserted between the stages of the first auxiliary amplifier, and a third electrically variable inserted in the input path of the second auxiliary amplifier of the first auxiliary amplifier distortion removal circuit Attenuating means and third electrically variable phase means; A third pilot signal detecting means inserted into an output path of the first auxiliary amplifier distortion removing circuit; an output of the third pilot signal detecting means is input to the third electric variable attenuating means; A third controller for controlling the variable phase means, a fourth electric variable attenuating means and a fourth electric variable phase means inserted into a linear signal transmission path of the first auxiliary amplifier distortion detection circuit, A second second pilot signal detecting means inserted into the input path of the second auxiliary amplifier of the auxiliary amplifier distortion removing circuit; and an input of the output of the second second pilot signal detecting means, the fourth electric variable A damping means, a fourth controller for controlling the fourth electric variable phase means, and the first electric variable attenuating means for minimizing a first pilot signal detection level detected by the first pilot signal detecting means. And on The first electrically variable phase means is controlled in a stepwise manner by the first controller, and the fourth electrically variable phase means is configured to minimize a second pilot signal detection level detected by the second second pilot detection means. The attenuating means and the fourth electric variable phase means are controlled step by step by the fourth controller, and the third electric signal is controlled so as to minimize the third pilot signal detection level detected by the third pilot signal detecting means. Variable attenuating means and the third electric variable phase means are controlled stepwise by the third controller, and minimize the second pilot signal detection level detected by the first second pilot signal detecting means. A control means for controlling the second electric variable damping means and the second electric variable phase means in a stepwise manner by the second controller. Foix Mode amplifier. 4. A distortion detection circuit for detecting non-linear distortion of a main amplifier, and amplifying the detected distortion component using a first auxiliary amplifier, and then injecting the amplified distortion component into an output of the main amplifier to cancel the distortion component. A first auxiliary amplifier distortion detecting circuit for detecting nonlinear distortion of the first auxiliary amplifier of the distortion removing circuit, and a second auxiliary amplifier for detecting a distortion component detected by the first auxiliary amplifier distortion detecting circuit. A first auxiliary amplifier distortion removal circuit for canceling the distortion component of the first auxiliary amplifier by re-injecting it into the output of the first auxiliary amplifier and re-injecting it into the output of the main amplifier. Means inserted into the input path of the feedforward amplifier to inject the first pilot signal; first electric variable attenuation means and first electric variable phase means inserted into the input path of the main amplifier of the distortion detection circuit When A first pilot signal detecting means inserted in the input path of the distortion detection circuit for the first auxiliary amplifier, the output signal of the first pilot signal detecting means inputs,
A first controller for controlling the first electric variable attenuator and the first electric variable phase shifter, and a second electric inserted before a power divider at an input of the first auxiliary amplifier distortion detection circuit. Variable attenuating means, second electrically variable phase means, means inserted between the stages of the main amplifier of the distortion detection circuit and injecting a second pilot signal, and a second inserted in the output path of the distortion removal circuit. A second pilot signal detecting unit, a second controller for receiving an output of the second pilot signal detecting unit, and controlling the second electric variable attenuator and the second electric variable phase shifter; Means inserted between amplifier stages for injecting a third pilot signal; third electric variable attenuating means inserted into the input path of the second auxiliary amplifier of the first auxiliary amplifier distortion removal circuit; Variable phase means, and the first auxiliary amplifier Means for injecting a fourth pilot signal inserted into the input path of the distortion detection circuit for use, fourth electric variable attenuating means and fourth electricity inserted in the linear signal transmission path of the distortion detection circuit for the first auxiliary amplifier. Variable phase means, third pilot signal detecting means inserted into the output path of the first auxiliary amplifier distortion removing circuit, and the output of the third pilot signal detecting means is input to the third electric variable attenuation. Means, a third controller for controlling the third electrically variable phase means, a fourth pilot signal detecting means inserted in an input path of a second auxiliary amplifier of the first auxiliary amplifier distortion removing circuit, A fourth controller which receives an output of the pilot signal detecting means and controls the fourth electric variable attenuating means and the fourth electric variable phase means; and a first pilot detected by the first pilot signal detecting means. The first electric variable attenuating means and the first electric variable phase means are controlled stepwise by the first controller so as to minimize the signal detection level, and the second detected by the second pilot detecting means. The second electric variable attenuating means and the second electric variable phase means are controlled stepwise by the second controller so as to minimize the pilot signal detection level, and are detected by the third pilot signal detecting means. The third electric variable attenuation means and the third electric variable phase means are controlled stepwise by the third controller so as to minimize the third pilot signal detection level, and the fourth pilot signal detection means Control means for controlling the fourth electric variable attenuating means and the fourth electric variable phase means in a stepwise manner by the fourth controller so as to minimize the fourth pilot signal detection level detected in Feedforward amplifier with dual loop, characterized in that it is.