JP2004165783A - Feedforward distortion compensation amplifying method and apparatus thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To automatically cancel a nonlinear distortion component of a main amplifier without using a pilot signal. <P>SOLUTION: In the feedforward distortion compensation amplifying method wherein a sub amplifier amplifies a nonlinear distortion component included in an output of a main amplifier amplifying an input signal and a directional coupler composes an output of the main amplifier with an output of the sub amplifier, synchronization detection is applied to part of an output of the directional coupler on the basis of the input signal to the sub amplifier or the output signal from the sub amplifier and the gain and the phase of the sub amplifier are controlled depending on an output of the synchronization detection. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a feedforward distortion compensation amplification method and apparatus, and more particularly, to a feedforward distortion compensation amplification method capable of automatically canceling and compensating for nonlinear distortion generated in a main amplifier, and a method thereof. Equipment related.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a feedforward distortion compensation amplification device has been known as an amplification device for amplifying an input signal. In such a conventional feedforward distortion compensation amplification device, a pilot signal is used to cancel a nonlinear distortion component generated in a main amplifier. Has been made to use.
[0003]
That is, in the conventional feedforward distortion compensating and amplifying apparatus, the nonlinear distortion generated in the main amplifier is automatically compensated by controlling the phase and the gain so that the output of the pilot signal is minimized.
[0004]
Here, FIG. 6 shows an example of a block configuration diagram of the conventional feedforward distortion compensating and amplifying device as described above.
[0005]
6 includes a pilot signal oscillator (pilot OSC) 604 that generates a pilot signal and outputs the generated pilot signal to main amplifier 602. Main amplifier 602 converts the pilot signal together with the input signal to power. Amplifying.
[0006]
More specifically, the feedforward distortion compensating and amplifying device 600 includes a first directional coupler (B) that branches and outputs an input signal input to an input terminal (not shown) of the feedforward distortion compensating and amplifying device 600. CDC1) 606, a main amplifier 602 connected to one output side of the first directional coupler 606, and a second directivity connected to the output side of the main amplifier 602 to branch the output of the main amplifier 602 A coupler (CDC2) 608; a first delay circuit (DL1) 610 connected to the other output side of the first directional coupler 606 to delay the other output of the first directional coupler 606; , A second delay circuit (DL2) 612 connected to one output side of the second directional coupler 608 to delay one output of the second directional coupler 608, and a first delay circuit 610. Connect to output side of And a third output connected to the other output side of the second directional coupler 608 to combine the output of the first delay circuit 610 with the other output of the second directional coupler 608 and output the combined output. A directional coupler (CDC3) 614, a fourth directional coupler (CDC4) 616 connected to the output side of the third directional coupler 614 and branching the output of the third directional coupler 614; , A sub-amplifier 618 connected to one output side of the fourth directional coupler 616, and a second sub-amplifier connected to the output side of the second delay circuit 612 and connected to the output side of the sub-amplifier 618. A fifth directional coupler (CDC5) 620 that combines and outputs the output of the delay circuit 612 and the output of the sub-amplifier 618; and a fifth directional coupler 620 connected to the output side of the fifth directional coupler 620. Direction for Dividing Output of Sex Coupler 620 A combiner (CDC6) 622 (one output of the sixth directional coupler 622 is output from an output terminal (not shown) of the feedforward distortion compensation amplifier 600 to the outside, and the feedforward distortion compensation amplifier 600), a band-pass filter (BPF) 624 connected to the other output side of the sixth directional coupler 622, a pilot signal to generate the main amplifier 602 and the synchronous detection circuit 626. (To be described later) and a band-pass filter connected to the output side of the band-pass filter 624 and to the output side of the pilot-signal oscillator 604, using the pilot signal as a synchronous detection signal. 624 is a synchronous detection circuit that performs synchronous detection on the output of 624 to obtain synchronous detection outputs (detection output Q and detection output I). Path / IQ Detector 626 and a phase / gain adjustment for controlling the phase and gain of the sub-amplifier 618 by processing the output (synchronous detection output) of the synchronous detection circuit 626 by being connected to the output side of the synchronous detection circuit 626 Information (In this specification, a signal for controlling the phase and gain of an amplifier is referred to as “phase / gain adjustment information”. ) And outputs it to the sub-amplifier 618 (a first signal processing circuit 628), and a power detection circuit (power detection) 630 connected to the other output side of the fourth directional coupler 616. And an output side of the power detection circuit 630 for processing the output (power detection output) of the power detection circuit 630 to generate phase / gain adjustment information for controlling the phase and gain of the main amplifier 602, And a second signal processing circuit (signal processing 2) 632 for outputting to the amplifier 602.
[0007]
In the above configuration, the input signal branched in first directional coupler 606 is power-amplified in main amplifier 602 together with the pilot signal generated by pilot signal oscillator 604.
[0008]
Then, the output of the main amplifier 602 is branched by the second directional coupler 608, and one output branched by the second directional coupler 608 passes through the second delay circuit 612 to the fifth direction. The directional coupler 620 combines the output with the output of the sub-amplifier 618, and further passes through the sixth directional coupler 622 to become an output signal.
[0009]
On the other hand, the other output branched by the second directional coupler 608 is branched by the first directional coupler 606 and passed through the first delay circuit 610 in the third directional coupler 614. Combined with the input signal. The input signal components are canceled by this combination, and the remaining output of the third directional coupler 614 becomes the nonlinear distortion component of the main amplifier 602 and the pilot signal component.
[0010]
Then, the output of the third directional coupler 614 is branched by the fourth directional coupler 616, and one output branched by the fourth directional coupler 616 is amplified by the sub-amplifier 618, The fifth directional coupler 620 combines the output with the output of the main amplifier 602.
[0011]
Therefore, if the gain and phase of the sub-amplifier 618 are appropriate, the nonlinear distortion component and the pilot signal component of the main amplifier 602 are canceled by the combination in the fifth directional coupler 620.
[0012]
In other words, if a pilot signal component exists in the output of the fifth directional coupler 620, the nonlinear distortion component of the main amplifier 602 also remains in the output of the fifth directional coupler 620.
[0013]
Here, in order to control the gain and the phase of the sub-amplifier 618 so that the nonlinear distortion component and the pilot signal component of the main amplifier 602 are canceled by the combination in the fifth directional coupler 620, the sixth directional coupling is performed. A part of the output of the fifth directional coupler 620 is extracted by the coupler 622, only the pilot signal component is selected by the band-pass filter 624 from the extracted output, and the pilot signal oscillator 604 is detected by the synchronous detection circuit 626. The synchronous detection is performed using the pilot signal generated by the above as a synchronous detection signal.
[0014]
The fact that the synchronous detection output, which is the output of the synchronous detection circuit 626, is large indicates that the nonlinear distortion component of the main amplifier 602 included in the output signal of the feedforward distortion compensation amplification device 600 is not canceled. Accordingly, the first signal processing circuit 628 processes the synchronous detection output in the first signal processing circuit 628 so that the synchronous detection output is reduced, that is, the gain and phase of the sub-amplifier 618 are controlled so as to minimize the pilot signal component. The phase / gain adjustment information for controlling the amplifier 618 is generated, and the phase and gain of the sub-amplifier 618 are controlled based on the generated phase / gain adjustment information.
[0015]
Here, in feed-forward distortion compensation amplification apparatus 600, the frequency of the pilot signal generated by pilot signal oscillator 604 is set outside the frequency band of the input signal, and the output of main amplifier 602 and the output of sub-amplifier 618 are output. After the combination, the pilot signal components are selected by the band-pass filter 624.
[0016]
In order to better detect the pilot signal component, by performing synchronous detection using a pilot signal and a signal obtained by rotating the phase of the pilot signal by 90 degrees as the synchronous detection signal, the synchronous detection output by both synchronous detection signals is used. Although it is possible to derive phase / gain adjustment information for controlling the phase and gain of the sub-amplifier 618, in any case, the frequency of the pilot signal is adjusted to some extent so as not to be affected by the input signal band. It must be kept away from the frequency band of the signal.
[0017]
On the other hand, the frequency of the pilot signal is converted to an intermediate frequency (IF), and the frequency is converted to the intermediate frequency in order to increase the detection sensitivity of the pilot signal component without keeping the frequency of the pilot signal too far from the frequency band of the input signal. A method of synchronously detecting the pilot signal using an intermediate frequency signal is also employed.
[0018]
Further, in the feedforward distortion compensating and amplifying apparatus 600, the power of the other output branched by the fourth directional coupler 616 is detected by the power detection circuit 630, and the second signal processing is performed in accordance with the detection result. The circuit 632 generates phase / gain adjustment information for controlling the main amplifier 602, and controls the power amplification of the input signal and the pilot signal by the main amplifier 602.
[0019]
However, various problems have been pointed out in such a conventional feed-forward distortion compensating amplifying apparatus as described below.
[0020]
That is, for example, considering the case where the feedforward distortion compensating and amplifying device is used for amplifying a transmission signal of a mobile phone, even if the pilot signal is controlled to be minimized, the frequency of the pilot signal is equal to the frequency band of the transmission signal. If the pilot signal level is not small enough to satisfy the regulations, a separate band-pass filter (BPF) for removing the pilot signals is provided in the circuit. There was a problem that it was necessary.
[0021]
Further, by inserting the bandpass filter for removing the pilot signal into the circuit, there is a problem that the power amplification by the main amplifier must be increased by the insertion loss of the bandpass filter.
[0022]
Also, the frequency band characteristics of the feedforward distortion compensating and amplifying device including the frequency of the pilot signal must be uniform in both amplitude and phase in a wide band so that the distortion component of the transmission signal is simultaneously canceled when the pilot signal is minimized. There was a problem that it did not become.
[0023]
[Problems to be solved by the invention]
The present invention has been made in view of the above-mentioned various problems of the conventional technology, and has as its object to automatically cancel nonlinear distortion components of a main amplifier without using a pilot signal. SUMMARY OF THE INVENTION It is an object of the present invention to provide a feedforward distortion compensation amplification method and an apparatus therefor.
[0024]
[Means for Solving the Problems]
In order to achieve the above object, a feedforward distortion compensation amplification method and apparatus according to the present invention uses an input signal directly instead of using a pilot signal.
[0025]
That is, the feedforward distortion compensation amplification method and apparatus according to the present invention synchronously detects a nonlinear distortion component in an output signal using a signal of a nonlinear distortion component of a main amplifier as a synchronous detection signal, and outputs the synchronous detection output (synchronous detection output). ) Controls the phase and gain of the sub-amplifier.
[0026]
In other words, the feedforward distortion compensation amplification method and apparatus according to the present invention uses an inter-modulation (IM) component of an input signal instead of using a pilot signal.
[0027]
That is, the invention according to claim 1 of the present invention amplifies the nonlinear distortion component included in the output signal of the main amplifier that amplifies the input signal by the sub-amplifier, and outputs the output signal of the main amplifier and the sub-amplifier. In a feedforward distortion compensation amplification method for combining an output signal with a directional coupler, a part of an output signal of the directional coupler is synchronously detected by an input signal to the sub-amplifier or an output signal from the sub-amplifier. The gain and the phase of the sub-amplifier are controlled in accordance with the output of the synchronous detection.
[0028]
In the invention according to claim 2 of the present invention, a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal is amplified by a sub-amplifier, and an output signal of the main amplifier and a signal of the sub-amplifier are amplified. In a feed-forward distortion compensation amplification method of combining an output signal with a directional coupler, an input signal to the sub-amplifier is synchronously detected by the input signal or a delay signal of the input signal, and the synchronous detection is performed according to an output of the synchronous detection. The gain and phase of the main amplifier are controlled, and a part of the output signal of the directional coupler is synchronously detected by an input signal to the sub-amplifier or an output signal from the sub-amplifier, and according to an output of the synchronous detection. Thus, the gain and phase of the sub-amplifier are controlled.
[0029]
According to a third aspect of the present invention, a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal is amplified by a sub-amplifier, and an output signal of the main amplifier and a signal of the sub-amplifier are amplified. In a feedforward distortion compensation amplification method for combining an output signal with a directional coupler, a part of the output signal of the directional coupler is combined with the input signal amplified by a third amplifier via a delay circuit. The combined signal is synchronously detected by an input signal to the sub-amplifier or an output signal from the sub-amplifier, and a gain and a phase of the sub-amplifier are controlled in accordance with an output of the synchronous detection. .
[0030]
According to a fourth aspect of the present invention, a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal is amplified by a sub-amplifier, and the output signal of the main amplifier and the sub-amplifier are amplified. In a feed-forward distortion compensation amplification method of combining an output signal with a directional coupler, an input signal to the sub-amplifier is synchronously detected by the input signal or a delay signal of the input signal, and the synchronous detection is performed according to an output of the synchronous detection. Controlling the gain and phase of the main amplifier, combining a part of the output signal of the directional coupler with the input signal amplified by the third amplifier via a delay circuit, and combining the combined signal with the auxiliary signal; Synchronous detection is performed by an input signal to an amplifier or an output signal from the sub-amplifier, and the gain and phase of the sub-amplifier are controlled according to the output of the synchronous detection. That.
[0031]
According to a fifth aspect of the present invention, there is provided a main amplifier for amplifying an input signal, a sub-amplifier for amplifying a nonlinear distortion component included in an output signal of the main amplifier, and an output signal of the main amplifier. And a directional coupler that combines the output signal of the sub-amplifier with the input signal to the sub-amplifier or the output of the sub-amplifier. A signal processing circuit that generates phase / gain adjustment information for controlling the gain and the phase of the sub-amplifier in accordance with the synchronous detection output of the synchronous detection circuit and outputs the information to the sub-amplifier. is there.
[0032]
According to a sixth aspect of the present invention, there is provided a main amplifier for amplifying an input signal, a sub-amplifier for amplifying a nonlinear distortion component included in an output signal of the main amplifier, and an output signal of the main amplifier. A directional coupler that combines the output signal of the directional coupler with the output signal of the directional coupler; and a first directional coupler that performs synchronous detection of a part of the output signal of the directional coupler based on an input signal to the auxiliary amplifier or an output signal from the auxiliary amplifier. And a first signal processing for generating phase / gain adjustment information for controlling the gain and phase of the sub-amplifier in accordance with the synchronous detection output of the first synchronous detection circuit and outputting the information to the sub-amplifier A second synchronous detection circuit for synchronously detecting an input signal to the sub-amplifier by the input signal or a delay signal of the input signal; and the main amplifier according to a synchronous detection output of the second synchronous detection circuit. of Obtained and generates a phase-gain adjustment information for controlling the phase is obtained as a second signal processing circuit for outputting to the main amplifier.
[0033]
According to a seventh aspect of the present invention, there is provided a main amplifier for amplifying an input signal, a sub-amplifier for amplifying a nonlinear distortion component included in an output signal of the main amplifier, and an output signal of the main amplifier. A first directional coupler for synthesizing the input signal and the output signal of the sub-amplifier; a delay circuit for delaying the input signal; a third amplifier for amplifying the input signal delayed by the delay circuit; A second directional coupler that combines a part of the output signal of the first directional coupler and the input signal amplified by the third amplifier, and an output signal of the second directional coupler A synchronous detection circuit that performs synchronous detection by an input signal to the sub-amplifier or an output signal from the sub-amplifier, and a phase / gain adjustment that controls a gain and a phase of the sub-amplifier according to a synchronous detection output of the synchronous detection circuit. Generate information Te is obtained by such a signal processing circuit for outputting to said auxiliary amplifier.
[0034]
The invention according to claim 8 of the present invention provides a main amplifier for amplifying an input signal, a sub-amplifier for amplifying a nonlinear distortion component included in an output signal of the main amplifier, and an output signal of the main amplifier. A first directional coupler for synthesizing the input signal and the output signal of the sub-amplifier; a delay circuit for delaying the input signal; a third amplifier for amplifying the input signal delayed by the delay circuit; A second directional coupler that combines a part of the output signal of the first directional coupler and the input signal amplified by the third amplifier, and an output signal of the second directional coupler A first synchronous detection circuit that performs synchronous detection based on an input signal to the sub-amplifier or an output signal from the sub-amplifier; and a gain and a phase of the sub-amplifier according to a synchronous detection output of the first synchronous detection circuit. Phase / gain control to be controlled A first signal processing circuit for generating information and outputting the information to the sub-amplifier; a second synchronous detection circuit for synchronously detecting an input signal to the sub-amplifier by the input signal or a delay signal of the input signal; A second signal processing circuit for generating phase / gain adjustment information for controlling the gain and phase of the main amplifier according to the synchronous detection output of the second synchronous detection circuit and outputting the information to the main amplifier; Things.
[0035]
Therefore, according to the invention described in each claim of the present invention, since the pilot signal is not used, the various problems described in the section of “Prior Art” caused by using the pilot signal are solved. Will not be invited.
[0036]
According to the invention described in each claim of the present invention, the output power of the main amplifier is reduced and the frequency band characteristics are easily ensured. Manufacturing costs can be greatly reduced.
[0037]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of a feedforward distortion compensation amplification method and apparatus according to the present invention will be described in detail with reference to the accompanying drawings.
[0038]
FIG. 1 is a block diagram showing an example of an embodiment of a feedforward distortion compensating amplifier according to the present invention.
[0039]
The feedforward distortion compensating and amplifying device 100 shown in FIG. 1 includes a first directional coupler (B) that branches and outputs an input signal input to an input terminal (not shown) of the feedforward distortion compensating and amplifying device 100. CDC1) 106, a main amplifier 102 connected to one output side of the first directional coupler 106 to power-amplify an input signal to the feedforward distortion compensating amplification device 100 as an output, and an output of the main amplifier 102 A second directional coupler (CDC2) 108 connected to the output side of the main amplifier 102 to branch the output signal of the main amplifier 102, and a first directional coupling connected to the other output side of the first directional coupler 106. A first delay circuit (DL1) 110 for delaying the other output of the second directional coupler 108 and one of the second directional couplers 108 connected to one output side of the second directional coupler 108; A second delay circuit (DL2) 112 for delaying a force, a first delay circuit connected to the output side of the first delay circuit 110 and connected to the other output side of the second directional coupler 108; A third directional coupler (CDC3) 114 that combines and outputs the output of the circuit 110 and the other output of the second directional coupler 108, and is connected to the output side of the third directional coupler 114 A fourth directional coupler (CDC4) 116 for branching the output of the third directional coupler 114 and a sub-amplifier 118 connected to one output side of the fourth directional coupler 116; A seventh directional coupler (CDC7) 119 connected to the output side of the sub-amplifier 118 and branching the output of the sub-amplifier 118; and a seventh directional coupler connected to the output side of the second delay circuit 112 and Connected to one output side of the coupler 119 and And one output of the seventh directional coupler 119 (one output of the seventh directional coupler 119 is obtained by branching the output signal from the sub-amplifier 118). A fifth directional coupler (CDC5) 120 that combines and outputs the output of the fifth directional coupler 120 and a sixth branch that is connected to the output side of the fifth directional coupler 120 and branches the output of the fifth directional coupler 120 A directional coupler (CDC6) 122 (one output of the sixth directional coupler 122 is output from an output terminal (not shown) of the feedforward distortion compensation amplifier 100 to the outside, and feedforward distortion compensation is performed. The output signal of the amplifying device 100) is connected to the other output side of the seventh directional coupler 119 and to the other output side of the sixth directional coupler 122, and Of the directional coupler 119 of (The other output of the seventh directional coupler 119 is obtained by branching the output signal from the sub-amplifier 118. ) As a synchronous detection signal, a synchronous detection circuit (IQ Detector) 126 for synchronously detecting the other output of the sixth directional coupler 122 to obtain synchronous detection outputs (detection outputs Q and I). It is connected to the output side of the detection circuit 126 and processes the output (synchronous detection output) of the synchronous detection circuit 126 to generate phase / gain adjustment information for controlling the phase and gain of the sub-amplifier 118, and to the sub-amplifier 118 A first signal processing circuit (signal processing 1) 128 for outputting, a power detection circuit (power detection) 130 connected to the other output side of the fourth directional coupler 116, and an output side of the power detection circuit 130 To generate phase / gain adjustment information for controlling the phase and gain of the main amplifier 102 to process the output (power detection output) of the power detection circuit 130 and output the information to the main amplifier 102 And a second signal processing circuit (signal processing 2) 132 that performs the processing.
[0040]
In the above configuration, the input signal to the feed-forward distortion compensation amplification device 100 branched in the first directional coupler 106 is power-amplified in the main amplifier 102.
[0041]
Then, the output signal from the main amplifier 102 is branched by the second directional coupler 108, and one of the outputs branched by the second directional coupler 108 is passed through the second delay circuit 112 to the fifth Is combined with one output of the seventh directional coupler 119, that is, the output signal from the sub-amplifier 118, and further passed through the sixth directional coupler 122, to compensate for feedforward distortion. It becomes the output signal of the amplification device 100.
[0042]
On the other hand, the other output branched by the second directional coupler 108 is branched by the first directional coupler 106 in the third directional coupler 114 and passed through the first delay circuit 110 The signal is combined with the input signal to the feedforward distortion compensation amplification device 100. By this combination, the input signal component to the feed-forward distortion compensating and amplifying device 100 is canceled, and the output of the third directional coupler 114 remaining as the canceled signal becomes the nonlinear distortion component of the main amplifier 102.
[0043]
Then, the output of the third directional coupler 114 is branched by the fourth directional coupler 116, and one output branched by the fourth directional coupler 116 is amplified by the sub-amplifier 118, The amplified signal from the sub-amplifier 118 is branched at the seventh directional coupler 119, and as described above, at the fifth directional coupler 120, one output of the seventh directional coupler 119, that is, The output signal from sub-amplifier 118 and the output signal from main amplifier 102 are combined.
[0044]
Therefore, if the gain and the phase of the sub-amplifier 118 are appropriate, the nonlinear distortion component of the main amplifier 102 is canceled by the combination in the fifth directional coupler 120.
[0045]
Here, the sixth directional coupler 122 controls the gain and phase of the sub-amplifier 118 so that the nonlinear distortion component of the main amplifier 102 is canceled by the combination in the fifth directional coupler 120. A part of the output of the directional coupler 120 is taken out and the other output branched by the seventh directional coupler 119 in the synchronous detection circuit 126 (the other output branched by the seventh directional coupler 119). Is obtained by splitting the output signal from the sub-amplifier 118) as a synchronous detection signal.
[0046]
The fact that the synchronous detection output, which is the output of the synchronous detection circuit 126, is large indicates that the nonlinear distortion component of the main amplifier 102 included in the output signal of the feedforward distortion compensation amplification device 100 is not canceled. Therefore, the first signal processing circuit 128 controls the synchronous detection output so that the synchronous detection output is reduced, that is, the gain and phase of the sub-amplifier 118 are controlled so that the nonlinear distortion component of the main amplifier 102 is minimized. Processing is performed to generate phase / gain adjustment information for controlling the sub-amplifier 118, and the phase and gain of the sub-amplifier 118 are controlled based on the generated phase / gain adjustment information.
[0047]
Further, in the feedforward distortion compensating and amplifying apparatus 100, the power of the other output branched by the fourth directional coupler 116 is detected by the power detection circuit 130, and the second signal processing is performed in accordance with the detection result. The circuit 132 generates phase / gain adjustment information for controlling the main amplifier 102, and controls the power amplification of the input signal to the feedforward distortion compensation amplification device 100 and the pilot signal by the main amplifier 102.
[0048]
That is, the above-described feedforward distortion compensating and amplifying apparatus 100 amplifies the nonlinear distortion component included in the output signal of the main amplifier 102 by the sub-amplifier 118, and the output signal of the main amplifier 102 and the fifth directional coupler 120. The output of the sixth directional coupler 122 which branches the output of the fifth directional coupler 120 (the output of the sixth directional coupler 122 is the feedforward distortion compensation amplifier 100) Is synchronously detected by the output of the seventh directional coupler 119, that is, the output signal from the sub-amplifier 118, and the sub-signal is output in accordance with the output of the synchronous detection (synchronous detection output). The gain and the phase of the amplifier 118 are controlled.
[0049]
More specifically, in the feed forward distortion compensation amplification device 100,
Fourth directional coupler 116-power detection circuit 130-second signal processing circuit 132-main amplifier 102-second directional coupler 108-third directional coupler 114-fourth directional coupling Bowl 116
Is formed, and this loop functions as a distortion detection loop for sufficiently canceling the output signal of the main amplifier 102 and the input signal to the feedforward distortion compensation amplification device 100. .
[0050]
In other words, by controlling the phase and gain of the main amplifier 102 so that the output of the fourth directional coupler 116 is minimized, the output of the fourth directional coupler 116 is mainly generated by the main amplifier 102. Most of the non-linear distortion components appear.
[0051]
Therefore, when the output signal of the sub-amplifier 118 for amplifying the output of the fourth directional coupler 116 is used as a synchronous detection signal and the output branched by the sixth directional coupler 122 is synchronously detected, only the nonlinear distortion component is obtained. Outputs synchronous detection. The input signal component to the feedforward distortion compensation amplification device 100 is output as noise, but becomes zero when averaged.
[0052]
Next, FIG. 2 is a block diagram showing another example of the embodiment of the feedforward distortion compensating and amplifying device according to the present invention. Note that the same or corresponding components as those of the feed-forward distortion compensating and amplifying device shown in FIG. 1 are denoted by the same reference numerals as those used in FIG. Description of the overlapping configuration and operation will be omitted.
[0053]
In the feed-forward distortion compensating and amplifying device 200 shown in FIG. 2, the output of the fourth directional coupler 116 is not simply detected by power, but is detected by a second synchronous detection circuit (synchronous detection circuit 2: IQ Detector) 204. 1 differs from the feedforward distortion compensating and amplifying apparatus shown in FIG. 1 in that synchronous detection is performed using an input signal to the feedforward distortion compensating and amplifying apparatus 200.
[0054]
That is, the feedforward distortion compensating and amplifying device 200 amplifies the nonlinear distortion component included in the output signal of the main amplifier 102 by the sub-amplifier 118, and combines the output signal of the main amplifier 102 with the fifth directional coupler 120. However, the input signal to the sub-amplifier 118 (the output of the fourth directional coupler 116) is converted to the input signal to the feedforward distortion compensation amplifier 200 (the output of the eighth directional coupler 202). ), The gain and phase of the main amplifier 102 are controlled in accordance with the output of the synchronous detection (synchronous detection output), and the output of the fifth directional coupler 120 is branched. A part of the output of the directional coupler 122 (the output of the sixth directional coupler 122 becomes the output signal of the feed-forward distortion compensating and amplifying device 100) is converted to the seventh directional coupling 119 output of, that is, the synchronous detection by the output signal from the sub-amplifier 118, in which so as to control the gain and phase of the auxiliary amplifier 118 in accordance with the output of the synchronous detection (synchronous detection output).
[0055]
More specifically, the feedforward distortion compensation amplification device 200 shown in FIG. 2 is connected to the other output side of the first directional coupler 106 to branch the other output of the first directional coupler 106. An eighth directional coupler (CDC8) 202 is provided, and one output of the eighth directional coupler (CDC8) 202 is input to the first delay circuit (DL1) 110. .
[0056]
Further, the feed-forward distortion compensation amplification device 200 is connected to the other output side of the fourth directional coupler 116 and to the other output side of the eighth directional coupler 202, A second synchronization in which the other output of the directional coupler 202 is used as a synchronous detection signal and the other output of the fourth directional coupler 116 is synchronously detected to obtain synchronous detection outputs (detection output Q and detection output I). A detection circuit 204 connected to the output side of the second synchronous detection circuit 204 for processing the output (synchronous detection output) of the second synchronous detection circuit 204 to control the phase and gain of the main amplifier 102; A second signal processing circuit (signal processing 2) 206 that generates gain adjustment information and outputs the information to the main amplifier 102;
[0057]
In the feedforward distortion compensation amplification device 200, the phase and the gain of the main amplifier 102 are controlled so that the synchronous detection output of the second synchronous detection circuit becomes zero.
[0058]
As a result, the input signal component in the output of the fourth directional coupler 116 over the input signal band to the feedforward distortion compensation amplification device 200 is different from the input signal to the feedforward distortion compensation amplification device 200 And the second synchronous detection circuit 204 detects the output of the fourth directional coupler 116 with the input signal, the signal component is included in the output of the fourth directional coupler 116. Since the ratio of the input signal component is eliminated, the phases and gains of the main amplifier 102 and the sub-amplifier 118 are controlled more correctly, and the nonlinear distortion can be sufficiently compensated.
[0059]
Here, in the feedforward distortion compensation amplification device 200 shown in FIG. 2, the input signal to the feedforward distortion compensation amplification device 200 (the output of the eighth directional coupler 202) is used as a synchronous detection signal. , The input signal to the sub-amplifier 118 (the output of the fourth directional coupler 116) is synchronously detected. However, the present invention is not limited to this. A signal obtained by delaying the input signal to the device 200 (for example, an output signal from the first delay circuit 110) is used as a synchronous detection signal, and the input signal to the auxiliary amplifier 118 (fourth directional coupling) is used. Output of the detector 116) may be synchronously detected.
[0060]
In the feedforward distortion compensating amplifier 100 shown in FIG. 1 or the feedforward distortion compensating amplifier 200 shown in FIG. 2, a part of the output signal of the sixth directional coupler 122 is converted to the output signal from the sub-amplifier 118. However, the present invention is not limited to this, and part of the output signal of the sixth directional coupler 122 may be synchronously detected by the input signal to the sub-amplifier 118. You may.
[0061]
Specifically, for example, FIG. 8 corresponding to the feed-forward distortion compensating / amplifying apparatus 700 shown in FIG. 7 corresponding to the feed-forward distortion compensating / amplifying apparatus 100 shown in FIG. 1 or FIG. As shown in the feedforward distortion compensating and amplifying device 800 shown in FIG. 6, a part of the output of the fifth directional coupler 120 is extracted by the sixth directional coupler 122 and the fourth directional coupling is performed by the synchronous detection circuit 126. The other output branched by the detector 116, that is, the input signal to the sub-amplifier 118 may be used as a synchronous detection signal for synchronous detection.
[0062]
Next, FIG. 3 is a block diagram showing another example of the embodiment of the feedforward distortion compensation amplification apparatus according to the present invention. 1 and FIG. 2 are denoted by the same reference numerals as those used in FIG. 1 and FIG. The description of the above is referred to, and the description of the overlapping configuration and operation will be omitted.
[0063]
The feedforward distortion compensating and amplifying device 300 shown in FIG. 3 amplifies the nonlinear distortion component included in the output signal of the main amplifier 102 by the sub-amplifier 118, and outputs the output signal of the main amplifier 102 and the fifth directional coupler 120. The output of the sixth directional coupler 122 that branches the output of the fifth directional coupler 120 (the output of the sixth directional coupler 122 is fed-forward distortion compensation amplification) A signal obtained by amplifying a part of the input signal to the feed-forward distortion compensating and amplifying device 300 by the third amplifier 306 via the third delay circuit (DL3) 304 is combined. The combined signal is synchronously detected by the output of the seventh directional coupler 119, that is, the output signal from the sub-amplifier 118, and the sub-amplification is performed according to the output of the synchronous detection (synchronous detection output). 118 is obtained by way to control the gain and phase of the.
[0064]
More specifically, the feed-forward distortion compensation amplification device 300 shown in FIG. 3 is connected to the output side of the first delay circuit 110 to branch the output of the first delay circuit 110 into a ninth directional coupler ( CDC 9) 302, and one output of the ninth directional coupler 302 is input to the third directional coupler 114.
[0065]
Further, the feedforward distortion compensating and amplifying device 300 includes a third delay circuit 304 connected to the other output side of the ninth directional coupler 302 to delay the other output of the ninth directional coupler 302. , A third amplifier 306 connected to the output of the third delay circuit 304, and the other output of the sixth directional coupler 122 and connected to the output of the third amplifier 306, A tenth directional coupler (CDC10) 308 that combines and outputs the other output of the sixth directional coupler 122 and the output signal of the third amplifier 306, and an output of the tenth directional coupler 308 A second power detection circuit (power detection 2) 310 connected to the power supply side and an output (power detection output) of the second power detection circuit 310 connected to the output side of the second power detection circuit 310 And the phase of the third amplifier 306 Signal processing circuit (signal processing 3) 312 for generating phase / gain adjustment information for controlling the gain and gain and outputting the information to the third amplifier 306, and the other output side of the seventh directional coupler 119 And the other end of the seventh directional coupler 119 is used as a synchronous detection signal, and the output of the tenth directional coupler 308 is connected to the output side of the tenth directional coupler 308. A first synchronous detection circuit (synchronous detection circuit 1: IQ detector) 326 for obtaining synchronous detection outputs (detection output Q and detection output I) by synchronous detection, and connected to an output side of the first synchronous detection circuit 326; First signal processing for processing the output (synchronous detection output) of the first synchronous detection circuit 326 to generate phase / gain adjustment information for controlling the phase and gain of the sub-amplifier 118 and outputting the information to the sub-amplifier 118 circuit( And a No. process 1) 328.
[0066]
In the feedforward distortion compensation amplifier 300, the feedforward distortion compensation amplified by the third amplifier 306 via the third delay circuit 304 before the synchronous detection of a part of the output signal of the feedforward distortion compensation amplifier 300 is performed. Since the signal component included in a part of the output signal is canceled by the input signal to the amplifying device 300, the input to the feedforward distortion compensation amplifying device 300 included in the output of the first synchronous detection circuit 326 is performed. The ratio of the signal component is reduced, the phase and gain of the sub-amplifier 118 are controlled more correctly, and the nonlinear distortion can be sufficiently compensated.
[0067]
Next, FIG. 4 is a block diagram showing another example of the embodiment of the feedforward distortion compensation amplification apparatus according to the present invention. Note that the same or corresponding components as those of the feedforward distortion compensating and amplifying device shown in FIGS. 1, 2 and 3 are denoted by the same reference numerals as those used in FIGS. 1, 2 and 3. 1, FIG. 2 and FIG. 3 are referred to, and redundant description of the configuration and operation will be omitted.
[0068]
4 amplifies the nonlinear distortion component included in the output signal of main amplifier 102 by sub-amplifier 118, and outputs the output signal of main amplifier 102 and fifth directional coupler 120. , The input signal to the sub-amplifier 118 (the output of the fourth directional coupler 116) is synchronously detected by the input signal to the feed-forward distortion compensating and amplifying device 400. The gain and phase of the main amplifier 102 are controlled by the detection output, and the output of the sixth directional coupler 122 that branches the output of the fifth directional coupler 120 (the output of the sixth directional coupler 122). Is an output signal of the feed-forward distortion compensating and amplifying device 100.) and a signal obtained by amplifying a part of the input signal by the third amplifier 306 via the third delay circuit (DL3) 304. And the combined signal is synchronously detected by the output of the seventh directional coupler 119, that is, the output signal from the sub-amplifier 118, and the sub-amplifier is output in accordance with the output of the synchronous detection (synchronous detection output). The gain and phase 118 are controlled.
[0069]
That is, the feedforward distortion compensating and amplifying apparatus 400 employs a synchronous detection method based on the input signal as shown in FIG. 2 and cancels the input signal component before detecting the nonlinear distortion component of the output signal as shown in FIG. Since the method of removing the input signal component is employed, the ratio of the input signal component included in the output of the first synchronous detection circuit 326 is further reduced, and the phase and gain of the sub-amplifier 118 are more completely controlled. Thus, nonlinear distortion compensation can be sufficiently performed.
[0070]
Here, in the feedforward distortion compensation amplifier 200 shown in FIG. 4, the input signal to the feedforward distortion compensation amplifier 400 (the output of the eighth directional coupler 202) is used as the synchronous detection signal. , The input signal to the sub-amplifier 118 (the output of the fourth directional coupler 116) is synchronously detected. However, the present invention is not limited to this. A signal obtained by delaying an input signal to the device 400 (for example, an output signal from the first delay circuit 110) is used as a synchronous detection signal, and an input signal to the sub-amplifier 118 (fourth directional coupling) is used. Output of the detector 116) may be synchronously detected.
[0071]
In the feed-forward distortion compensation amplifier 300 shown in FIG. 3 or the feed-forward distortion compensation amplifier 400 shown in FIG. 4, a part of the output signal of the sixth directional coupler 122 and the third delay circuit 304 are connected. The signal obtained by synthesizing the input signal amplified by the third amplifier 306 with the output signal from the sub-amplifier 118 is synchronously detected. However, the present invention is not limited to this. The signal may be synchronously detected by an input signal to the sub-amplifier 118.
[0072]
Specifically, for example, in FIG. 10 corresponding to the feedforward distortion compensating / amplifying device 900 shown in FIG. 9 corresponding to the feedforward distortion compensating / amplifying device 300 shown in FIG. 3 or the feedforward distortion compensating / amplifying device 400 shown in FIG. As shown in the feed-forward distortion compensating amplifier 1000 shown in the drawing, in the first synchronous detection circuit 326, the other output branched by the fourth directional coupler 116, that is, the input signal to the sub-amplifier 118 is synchronously detected. As a signal, a signal obtained by synthesizing a part of the output signal of the sixth directional coupler 122 and the input signal amplified by the third amplifier 306 via the third delay circuit 304 may be synchronously detected. Good.
[0073]
Also, in the feedforward distortion compensating amplifiers 300, 400, 900, and 1000 shown in FIGS. 3, 4, 9, and 10, the second power detection circuit is used to control the phase and the gain of the third amplifier 306. Although the power is detected by using (power detection 2), the third amplifier 306 performs synchronous detection on the output signal of the tenth directional coupler 308 using the input signal or the output signal of the third amplifier 306, and outputs the third amplifier. The phase and gain of 306 may be controlled.
[0074]
Here, FIG. 5 shows an example of the configuration of the synchronous detection circuit 126, the second synchronous detection circuit 204, and the first synchronous detection circuit 326 shown in FIGS. 1 to 4 and FIGS. .
[0075]
That is, the synchronous detection circuit 126, the second synchronous detection circuit 204, and the first synchronous detection circuit 326 are connected to a limiter amplifier (limiter AMP) 502 for amplifying the synchronous detection signal and an output side of the limiter amplifier 502 to be connected to the limiter. A 90-degree phase shifter 504 that rotates the phase of the output of the amplifier 502 by 90 degrees, and a detection output Q that is connected to the output side of the 90-degree phase shifter 504 and multiplies the output of the 90-degree phase shifter 504 by the signal to be detected. A first multiplier (multiplier 1) 506 to be obtained, and a second multiplier (multiplier) connected to the output side of the limiter amplifier 502 to obtain a detection output I by multiplying the output of the limiter amplifier 502 by the signal to be detected. 2) 508.
[0076]
In the above configuration, the synchronous detection signal is amplified by the limiter amplifier 502, and the synchronous detection signal whose phase is rotated by 90 degrees by the 90-degree phase shifter 504 is also generated. Therefore, the first multiplier 506 and the second multiplication are performed. When the detected signal is multiplied by the synchronous detection signal and the synchronous detection signal rotated by 90 degrees in the detector 508, a detection output I and a detection output Q corresponding to an in-phase component and a 90-degree phase shift are obtained as synchronous detection outputs.
[0077]
It should be noted that any of the detection outputs becomes a negative output when the phase of the detection signal is inverted from that of the detection signal.
[0078]
According to the embodiments of the present invention described above, a pilot signal source for generating a pilot signal is not required, and the output power of main amplifier 102 can be reduced as compared with the method using a pilot signal. It can be said that the band characteristics can be easily secured, and therefore, the effect on the reduction of the manufacturing cost and the like is remarkable.
[0079]
Is big.
[0080]
【The invention's effect】
Since the present invention is configured as described above, it has an excellent effect that the nonlinear distortion component of the main amplifier can be automatically canceled without using a pilot signal.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an example of an embodiment of a feedforward distortion compensation amplification device according to the present invention.
FIG. 2 is a block diagram showing another example of the embodiment of the feedforward distortion compensation amplification apparatus according to the present invention.
FIG. 3 is a block diagram showing another example of the embodiment of the feedforward distortion compensating and amplifying device according to the present invention.
FIG. 4 is a block diagram showing another example of the embodiment of the feedforward distortion compensating and amplifying device according to the present invention.
FIG. 5 is a block diagram illustrating an example of a configuration of a synchronous detection circuit illustrated in FIGS. 1 to 4;
FIG. 6 is a block diagram showing a conventional feed-forward distortion compensation amplification device.
FIG. 7 is a block diagram showing another example of the embodiment of the feedforward distortion compensating and amplifying device according to the present invention.
FIG. 8 is a block diagram showing another example of the embodiment of the feedforward distortion compensating and amplifying device according to the present invention.
FIG. 9 is a block diagram showing another example of the embodiment of the feedforward distortion compensation amplification apparatus according to the present invention.
FIG. 10 is a block diagram showing another example of the embodiment of the feedforward distortion compensation amplification device according to the present invention.
[Explanation of symbols]
100, 200, 300, 400, 600, 700, 800, 900, 1000 feed-forward distortion compensation amplifier
102, 602 Main amplifier
106,606 First directional coupler (CDC1)
108,608 Second directional coupler (CDC2)
110, 610 First delay circuit (DL1)
112, 612 Second delay circuit (DL2)
114, 614 Third directional coupler (CDC3)
116,616 Fourth directional coupler (CDC4)
118,618 Secondary amplifier
119 seventh directional coupler (CDC7)
120, 620 Fifth directional coupler (CDC5)
122, 622 Sixth directional coupler (CDC6)
126, 626 Synchronous detection circuit (IQ Detector)
128, 328, 628 First signal processing circuit (signal processing 1)
130, 630 Power detection circuit (power detection)
132, 206, 632 Second signal processing circuit (signal processing 2)
202 eighth directional coupler (CDC8)
204 Second Synchronous Detector (Synchronous Detector 2: IQ Detector)
302 ninth directional coupler (CDC9)
304 Third delay circuit (DL3)
306 Third amplifier
308 Tenth directional coupler (CDC10)
310 Second power detection circuit (power detection 2)
312 Third signal processing circuit (signal processing 3)
326 First Synchronous Detector (Synchronous Detector 1: IQ Detector)
502 Limiter Amplifier (Limiter AMP)
504 90 degree phase shifter
506 First Multiplier (Multiplier 1)
508 Second multiplier (multiplier 2)
604 Pilot signal oscillator (Pilot OSC)
624 band pass filter (BPF)

Claims (8)

A feed-forward distortion compensation amplifier for amplifying a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal by a sub-amplifier and combining an output signal of the main amplifier and an output signal of the sub-amplifier by a directional coupler. In the method,
A part of the output signal of the directional coupler is synchronously detected by an input signal to the sub-amplifier or an output signal from the sub-amplifier, and a gain and a phase of the sub-amplifier are controlled according to an output of the synchronous detection. And a feedforward distortion compensation amplification method. A feed-forward distortion compensation amplifier for amplifying a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal by a sub-amplifier and combining an output signal of the main amplifier and an output signal of the sub-amplifier by a directional coupler. In the method,
The input signal to the sub-amplifier is synchronously detected by the input signal or the delay signal of the input signal, and the gain and phase of the main amplifier are controlled in accordance with the output of the synchronous detection,
A part of the output signal of the directional coupler is synchronously detected by an input signal to the sub-amplifier or an output signal from the sub-amplifier, and a gain and a phase of the sub-amplifier are controlled according to an output of the synchronous detection. And a feedforward distortion compensation amplification method. A feed-forward distortion compensation amplifier for amplifying a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal by a sub-amplifier and combining an output signal of the main amplifier and an output signal of the sub-amplifier by a directional coupler. In the method,
A part of the output signal of the directional coupler is combined with the input signal amplified by the third amplifier via a delay circuit, and the combined signal is input to the sub-amplifier or the signal from the sub-amplifier. A feed-forward distortion compensation amplification method for synchronously detecting an output signal and controlling a gain and a phase of the sub-amplifier according to an output of the synchronous detection. A feed-forward distortion compensation amplifier for amplifying a non-linear distortion component included in an output signal of a main amplifier for amplifying an input signal by a sub-amplifier and combining an output signal of the main amplifier and an output signal of the sub-amplifier by a directional coupler. In the method,
The input signal to the sub-amplifier is synchronously detected by the input signal or the delay signal of the input signal, and the gain and phase of the main amplifier are controlled in accordance with the output of the synchronous detection,
A part of the output signal of the directional coupler is combined with the input signal amplified by the third amplifier via a delay circuit, and the combined signal is input to the sub-amplifier or the signal from the sub-amplifier. A feed-forward distortion compensation amplification method for synchronously detecting an output signal and controlling a gain and a phase of the sub-amplifier according to an output of the synchronous detection. A main amplifier for amplifying the input signal;
A sub-amplifier that amplifies a nonlinear distortion component included in the output signal of the main amplifier;
A directional coupler that combines the output signal of the main amplifier and the output signal of the sub-amplifier,
A synchronous detection circuit that performs synchronous detection on a part of the output signal of the directional coupler based on an input signal to the sub-amplifier or an output signal from the sub-amplifier,
A feed-forward distortion compensating and amplifying apparatus comprising: a signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the sub-amplifier according to the synchronous detection output of the synchronous detection circuit and outputs the information to the sub-amplifier. A main amplifier for amplifying the input signal;
A sub-amplifier that amplifies a nonlinear distortion component included in the output signal of the main amplifier;
A directional coupler that combines the output signal of the main amplifier and the output signal of the sub-amplifier,
A first synchronous detection circuit for synchronously detecting a part of the output signal of the directional coupler by an input signal to the sub-amplifier or an output signal from the sub-amplifier;
A first signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the sub-amplifier according to the synchronous detection output of the first synchronous detection circuit and outputs the information to the sub-amplifier;
A second synchronous detection circuit that synchronously detects an input signal to the sub-amplifier by the input signal or a delay signal of the input signal;
A second signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the main amplifier in accordance with the synchronous detection output of the second synchronous detection circuit and outputs the information to the main amplifier. Distortion compensation amplifier. A main amplifier for amplifying the input signal;
A sub-amplifier that amplifies a nonlinear distortion component included in the output signal of the main amplifier;
A first directional coupler that combines an output signal of the main amplifier and an output signal of the sub-amplifier;
A delay circuit for delaying the input signal;
A third amplifier for amplifying the input signal delayed by the delay circuit;
A second directional coupler that combines a part of the output signal of the first directional coupler and the input signal amplified by the third amplifier;
A synchronous detection circuit for synchronously detecting an output signal of the second directional coupler based on an input signal to the sub-amplifier or an output signal from the sub-amplifier;
A feed-forward distortion compensating and amplifying apparatus comprising: a signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the sub-amplifier according to the synchronous detection output of the synchronous detection circuit and outputs the information to the sub-amplifier. A main amplifier for amplifying the input signal;
A sub-amplifier that amplifies a nonlinear distortion component included in the output signal of the main amplifier;
A first directional coupler that combines an output signal of the main amplifier and an output signal of the sub-amplifier;
A delay circuit for delaying the input signal;
A third amplifier for amplifying the input signal delayed by the delay circuit;
A second directional coupler that combines a part of the output signal of the first directional coupler and the input signal amplified by the third amplifier;
A first synchronous detection circuit that synchronously detects an output signal of the second directional coupler based on an input signal to the sub-amplifier or an output signal from the sub-amplifier;
A first signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the sub-amplifier according to the synchronous detection output of the first synchronous detection circuit and outputs the information to the sub-amplifier;
A second synchronous detection circuit that synchronously detects an input signal to the sub-amplifier by the input signal or a delay signal of the input signal;
A second signal processing circuit that generates phase / gain adjustment information for controlling the gain and phase of the main amplifier in accordance with the synchronous detection output of the second synchronous detection circuit and outputs the information to the main amplifier. Distortion compensation amplifier.

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