JP2014013997A - Radio communication device having nonlinear amplifier, and distortion reduction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a distortion caused in an amplifier of a radio communication device without using complicated techniques.SOLUTION: A distortion reduction circuit provided includes: a first local signal source 1001 for outputting a first local signal of a first local frequency f; a second local signal source 1007 for outputting a second local signal of a second local frequency f; a signal combiner 1005 for adding up the first local signal and the second local signal; a mixer 1002 for up-converting a transmission input signal of a frequency fwith an output signal of the signal combiner 1005; and an amplifier 1003 for amplifying an output signal of the mixer 1002. The second local frequency fis set to 2f±for 2f±3f.

Description

  The present invention relates to a technique for reducing distortion generated in a nonlinear amplifier of a wireless communication apparatus.

  FIG. 14 shows a simplified block diagram of a conventional wireless communication apparatus. In the wireless communication apparatus of FIG. 14, the input signal from the transmission signal input terminal 1000 is mixed and up-converted with the signal from the local signal source 1001 in the mixer 1002, amplified by the amplifier 1003, and output from the output terminal 1004. Since this figure is a simplified block diagram, in an actual wireless communication device, in addition to the one shown in this block diagram, elements for removing unnecessary waves by various filters, stepwise up-conversion by multiple mixers, multiple In some cases, a stage amplifier is used. Further, as a modulation signal from the transmission signal input terminal 1000, a simple sine wave (Continuous Wave: CW) may be used, or a modulation signal having a band may be used. Since these matters are not important points in the description of the present invention, they are omitted here.

  The amplifier used in this conventional wireless communication apparatus is a non-linear element in most cases, and distortion caused by non-linearity occurs in the amplified signal. These distortions include intermodulation distortion (IMD) and harmonic distortion (HD) when the signal from the transmission signal input terminal 1000 is a composite wave of one or more CW frequencies. What is called is observed. On the other hand, when the input signal is a modulated wave, it is observed as adjacent channel leakage power (Adjacent Channel Power Ratio: ACPR or Adjacent Channel Leakage Ratio: ACLR).

Intermodulation distortion and harmonic distortion are unwanted wave signals observed at nf ₁ ± mf ₂ (where n and m are integers of 0 or more) when the frequency of the signal input to the amplifier is f ₁ and f _2. If IMD (n + m) (n + m-order intermodulation distortion) or n or m is 0, the form of HDn or HDm (n-order or m-order harmonic distortion) (for example, 2 The next intermodulation distortion is called IMD2, 3 intermodulation distortion is IMD3, the second harmonic distortion is HD2, and the third harmonic distortion is HD3). This is shown on the frequency axis in FIG. ACPR can be thought of as an integral of IMD3 between individual signals constituting a signal having a band, and as shown in Non-Patent Document 1, it is known that there is a correlation between the magnitude of ACPR and IMD3. It has been.

  These distortions may interfere with adjacent channel signals or reduce the power of the main signal when observed at the same frequency as the main signal. It was a challenge.

  Conventionally, as a method for suppressing the distortion, a method of generating a signal having a phase opposite to that of the distortion and canceling the distortion is generally used. Examples thereof are shown in Patent Document 1 to Patent Document 9.

  Patent Document 1 shows the following operation from FIG. 1 of the document. The IMD3 generated in the first amplifier 11 is phase-inverted by the phase inversion unit 12, thereby canceling out the IMD3 generated in the second amplifier 13.

  Patent Document 2 shows the following operation from FIG. 2 of the document. The distortion from the amplifier 203 is reduced by extracting the distortion from the output signal of the amplifier 203 by the distribution circuit 205 and the detection circuit 210 and feeding back to the output of the amplifier via the injection circuit 223.

  Patent Document 3 shows the following operation from FIG. 2 or FIG. 3 of the document. In this configuration, the output of the amplifier is monitored, the result is applied to an analog-to-digital converter (ADC), and an arithmetic operation with an input signal or the like is performed to extract only the distortion component. A digital block that generates an I / Q signal generates a distortion having an antiphase (polynomial predistortor 301), and cancels the distortion generated by the amplifier 103. In the method of Patent Document 3, there are many different variations such as a feedback method (the number of points to be monitored and a feedback configuration method) and an arithmetic expression in a digital block. As an example, Patent Document 4 exists.

  Patent Document 5 shows the following operation from FIGS. 1 to 7 of the document. Even in this configuration, the output of the amplifier is monitored and the result is fed back as in the configuration of Patent Document 3. However, unlike Patent Document 3, the feedback signal is not digitized, and only the distortion component is extracted by calculating the input signal as an analog signal. The distortion in the output is reduced by adding the signal of the distortion component to the input with the opposite phase.

  Patent Document 6 shows the following operation from FIG. 4 of the document. In this configuration, the input signal is divided into two paths, normally amplified in one path, amplified by inverting only the phase of IMD3 in the other path, and adding both to double the in-phase main signal However, IMD3 whose phase is reversed cancels out. The method of Patent Document 7 is also a variation, and the mixer used is one that performs carrier wave suppression, but the principle is the same.

  Patent Document 8 shows the following operation from FIGS. 1 and 3 of the document. In this configuration, the input signal is branched, and a square detector is used in one path and is modulated by a mixer (PM modulator). As a result, a signal having the same frequency as the secondary distortion (however, on the low frequency side) is generated and added to the input signal. As a result, the IMD2 generated from the secondary distortion in the amplifier cancels out the IMD3 generated from the original signal, and the distortion is reduced. From FIG. 1 to FIG. 3 of Patent Document 9 as well, the basic operation principle is the same as that of Patent Document 8. In the case of this Patent Document 9, the difference is that the same signal as the second-order distortion is calculated from the original input signal without using the square detector.

Japanese Unexamined Patent Publication No. 2000-332657 JP 2003-174334 A Japanese Patent No. 4835241 JP 2009-111958 A Japanese Patent No. 3337766 International Publication No. 2007/123040 JP 59-158113 A Japanese Patent No. 3696121 Japanese Patent No. 3342746

Maxim (MAXIM) Application Note 3902 “Calculating Adjacent Channel Leakage Power Ratio (ACLR) in General Purpose RF Devices” (http://www.maxim-ic.com/app-notes/index.mvp/id/3902)

  However, there are some problems with these conventional configurations.

  In the method of Patent Document 1, there are a problem that current consumption increases and a problem that designability deteriorates. In general, an amplifier tends to increase in distortion corresponding to output power, and this is represented by a third-order intercept point (OIP3). The magnitude of the generated distortion is given by the following equation (1), and it is necessary to use a second-stage amplifier having a gain (amplification factor) higher than that of the first-stage OIP3.

  Such an element with high OIP3 is an element that maintains linearity up to high power and has a feature of high current consumption. Therefore, when an amplifier having the same gain as that of another method is formed, the current becomes large. Further, when designing a level diagram of a radio communication device, design is deteriorated because the gain and distortion of an amplifier to be used are restricted.

  Although the method of Patent Document 2 performs feedback in the output signal, it is a good method for considering distortion compensation, but has a problem that it cannot be used at high power. This is because, when this circuit is used with high power, each element in the circuit needs to be compatible with high power. In particular, the signal oscillation device 220 of FIG. 2 is configured when the output is large. Becomes very difficult.

  In the method of Patent Document 3, there is a problem that it takes time until the increase in the number of elements used and the reduction in distortion are stabilized. This is because feedback is used and elements such as AD converters are included in the circuit for re-conversion to digital, so it takes time to increase these elements and stabilize the feedback loop. is there. This also applies to Patent Document 4 in which feedback to the same digital circuit is performed. Even in the case of Patent Document 5 in which feedback is an analog circuit, there is a similar problem of increase in elements.

  The method of Patent Document 6 has a problem that it is difficult to use at high output and a problem that the number of elements used increases. In FIG. 4 of this document, since the powers of the amplifier 61 and the amplifier 62 are combined, both of them need to be substantially equivalent amplifiers. This synthesis is not a problem if the output is low, but there are few means for low-loss synthesis of high-power signals. A problem occurs. In addition, there are problems that the number of elements used is increased although the number of paths is divided into two and an amplifier is required for each of the paths, which is smaller than the methods of Patent Documents 1 to 6. This also causes the same problem in Patent Document 7.

  The technique of Patent Document 8 and the technique of Patent Document 9 have a problem of increasing the number of elements used. In the case of Patent Document 8, in the case of Patent Document 9, in the case of Patent Document 9, a circuit for calculating the second harmonic from the input signal is required, and as a point common to both, in order to input it to the amplifier circuit In order to match the amplitude and frequency, additional elements such as a mixer, an amplifier, and a filter are required in addition to the original circuit.

  As described above, the conventional invention has a problem that the number of elements increases. In particular, an increase in the number of amplifiers with large current consumption and large size is accompanied by an increase in the size of devices and circuits, and there is a problem in that the design is deteriorated such as adjustment of plural paths and feedback.

  The present invention provides a distortion compensation circuit that solves these problems, minimizes the increase in the number of elements, and can cope with any amplifier non-linearity without causing deterioration in designability. With the goal.

According to an aspect of the present invention, a first local oscillator that outputs a first local signal having a first local frequency f _LO1 , a second local oscillator that outputs a second local signal having a second local frequency f _LO2 , and An adder for adding the first local signal and the second local signal, a mixer for up-converting a transmission input signal having a frequency of f _IF, and amplifying the output signal of the mixer using the output signal of the adder An amplifier, wherein the second local frequency f _LO2 is set to 2f _LO1 ± f _IF or 2f _LO1 ± 3f _IF .

  In the present invention, IMD2 generated by the same amplifier is used to reduce IMD3, so that distortion generated from the same nonlinear element is different from the conventional method in which distortion is generated using different amplifiers and nonlinear elements. Therefore, it is possible to reduce distortion more accurately.

  Another advantage is that no additional elements are required because the mixer or modulator provided in the wireless communication device is used to generate a signal having the same frequency as the input second-order intermodulation distortion. Although there is a point that a plurality of frequencies are required as a local signal, since the frequency is almost doubled, there is an advantage that it is only necessary to add a frequency dividing circuit of the oscillation circuit used and a phase adjusting circuit thereof.

  Further, in the present invention, it is only necessary to change the signal frequency input to the mixer or the modulator, so that there is an advantage that the level diagram itself does not need to be largely reviewed.

Block diagram of the first embodiment of the present invention Angular frequency of IMD3 (with ω _LO1 offset. 0 point becomes ω _LO1 ) Angular frequency of IMD2 generated in the first embodiment of the present invention (with an offset of ω _LO2 −ω _LO1 , a point of 0 becomes ω _LO2 −ω _LO1 ) Angular frequency of IMD2 generated in the second embodiment of the present invention (with an offset of ω _LO2 −ω _LO1 , a point of 0 becomes ω _LO2 −ω _LO1 ) Angular frequency of IMD2 generated in the third embodiment of the present invention (with an offset of ω _LO2 −ω _LO1 , a point of 0 becomes ω _LO2 −ω _LO1 ) Angular frequency of IMD2 generated in the fourth embodiment of the present invention (with an offset of ω _LO2 −ω _LO1 , a point of 0 becomes ω _LO2 −ω _LO1 ) Angular frequency of IMD2 generated in the fifth embodiment of the present invention (with an offset of ω _LO2 −ω _LO1 , a point of 0 becomes ω _LO2 −ω _LO1 ) Angular frequency, amplitude and phase shift of IMD3 generated in the present invention Angular frequency, amplitude, and phase shift of IMD2 generated in the first embodiment of the present invention Angular frequency, amplitude, and phase shift of IMD2 generated in the second embodiment of the present invention Angular frequency, amplitude, and phase shift of IMD2 generated in the third embodiment of the present invention Angular frequency, amplitude, and phase shift of IMD2 generated in the fourth embodiment of the present invention Angular frequency, amplitude, and phase shift of IMD2 generated in the fifth embodiment of the present invention Relationship between input power (output of signal source 1000) and distortion Block diagram of the second embodiment of the present invention Block diagram of the third embodiment of the present invention Block diagram of the fourth embodiment of the present invention Block diagram of the fifth embodiment of the present invention Block diagram of the sixth embodiment of the present invention The block diagram of the 6th Embodiment of this invention (a structure different from FIG. 9) The block diagram of the 6th Embodiment of this invention (a structure different from FIG. 9, FIG. 10) Block diagram of the seventh embodiment of the present invention The block diagram of the 7th Embodiment of this invention (a structure different from FIG. 12) Configuration of conventional wireless communication device Intermodulation distortion and harmonic distortion generated from two input signals

In each embodiment of the present invention, IMD3 that is difficult to be removed by a filter because the frequency is close among distortions that are unnecessary waves of an amplifier output signal is reduced by using IMD2 generated from the same amplifier. Usually, when the input signal is a signal having two adjacent f ₁ and f ₂ frequencies, the IMD2 appears at a frequency that is significantly different from the main signal, as described above, such as f ₁ + f ₂ and f ₁ -f ₂ . Occurs between the signals of the frequencies f ₁ and f ₂ by inputting a signal having the same frequency as the second-order intermodulation distortion such as 2f ₁ , 2f ₂ , and f ₁ + f ₂ to the input signal. IMD2 has the same frequency as IMD3, reducing IMD3. In order to generate a signal having the same frequency as the second-order intermodulation distortion, not only the local signal of the original frequency but also twice the frequency of the local signal used for the mixer or modulator arranged before the amplifier is used. This is achieved by adding a local signal.

In other words, the first local signal (angular frequency f _LO1 ) and the second local signal (f _LO2 ) are input to the mixer arranged in front of the amplifier, and the transmission signal is transmitted from the first local signal to the second local signal. The signal for distortion suppression is generated from the local signal. In the amplifier, IMD3 generated from the transmission signal and IMD2 generated from the transmission signal and the signal for distortion suppression are generated, and both are canceled to reduce distortion.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a first embodiment of the present invention. In FIG. 1, a first local signal source 1001 (first local oscillator) is connected to a first input terminal of a signal synthesizer 1005 (adder), and a second local signal source 1007 (second local oscillator) is The signal synthesizer 1005 is connected to a second input terminal via a phase shifter 1006 that adjusts the phase of the signal. The signal synthesizer 1005 adds the output signal (first local signal) from the first local signal source 1001 and the output signal (second local signal) from the second local signal source 1007. The mixer 1002 is an element having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the signal to the output terminal. The mixer 1002 transmits the signal to the first input terminal of the mixer 1002. The signal of the signal input terminal 1000 is input, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer 1002. The mixer 1002 uses the output signal of the signal synthesizer 1005 to up-convert a transmission input signal whose frequency is f _IF . The output terminal of the mixer is connected to the input terminal of the amplifier 1003. The amplifier 1003 amplifies the output signal of the mixer 1002. The output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit.

The first local signal source 1001 and the second local signal source 1007 have a signal frequency (first local frequency f _LO1 ) of the first local signal source as f _0, and a signal frequency input from the transmission signal input terminal 1000 the case of the f _IF,, the second local signal source signal frequency (second local frequency f _LO2) has a 2f ₀ ± f _IF relationship. Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed. The signal frequency of the second local signal source (second local frequency f _LO2 ) may have a relationship of 2f ₀ ± 3f _IF .

Next, the principle of operation of the present embodiment will be described with reference to FIGS. To simplify the explanation, let the signal from the transmission signal input terminal 1000 be two adjacent angular frequencies ω _IF1 and ω _IF2 (ω _IF1 <ω _IF2 ), the phase difference is φ _IF , the amplitude is A, and the first When the angular frequency from the local signal source is ω _LO1 , the phase difference is φ _LO1 , the amplitude is B ₁ , the angular frequency from the second local signal source is ω _LO2 , the phase difference is φ _LO2 , and the amplitude is B ₂ Will be described.

In this case, the signal P _IF from the transmission signal input terminal 1000 is expressed by the following equation (2), where φ _IF is the phase difference between the two signals.

  On the other hand, the local signal (output of the signal synthesizer 1005) is expressed by the following equation (3).

  As a result, the output of the mixer 1002 is expressed by the following equation (4).

In other words, the output of the mixer is ω _LO1 + ω _IF1 , ω _LO1 + ω _IF2 , ω _LO1 -ω _IF1 , ω _LO1 -ω _IF2 , ω _LO2 + ω _IF1 , ω _LO2 + ω _IF2 , ω _LO2 -ω _IF1 , ω _LO2 -ω _IF2 , 8 types of angular frequency signals are generated. In order to distinguish these eight types of signals, signals of each angular frequency are called as follows. ω _LO1 + ω _IF1 , ω _LO1 + ω _IF2 , the main signal, ω _LO1 -ω _IF1 , ω _LO1 -ω _{IF2 the} main image, ω _LO2 + ω _IF1 , ω _LO2 + ω _IF2 2nd harmonic ”, ω _LO2 -ω _IF1 , ω _LO2 -ω _IF2 are 2nd harmonic image, the main signal amplitude is A _M , the main signal image amplitude is A _MI , and the 2nd harmonic amplitude is the amplitude of a _D, 2 harmonic images and a _DI.

These signals are input to the amplifier 1003. Since the amplifier 1003 is a non-linear amplifier, the output P _OUT is generally in the relationship expressed by the following equation (5) with respect to the input P _IN . However, k0, k1, k2, and k3 are constants determined by the nonlinearity of the amplifier.

In this expression, IMD2 is output from the even-order term and IMD3 is output from the odd-order term of the third power or higher, so IMD2 and IMD3 can be approximated by considering only the highest-contributing second and third power terms. Can be calculated. Since there are many angular frequencies calculated by substituting Eq. (4) into Eq. (5), the main signals ω _LO1 + ω _IF1 and ω _LO1 + ω _IF2 are near the two angular frequencies. A signal that appears will be described.

  As shown in the tables of FIG. 3A and FIG. 3B, several signals are observed in the adjacent IMD2 and IMD3 signals, and each has a different phase. In the conventional configuration (FIG. 14), since the second local signal source 1007 does not exist, only IMD3 is observed in the vicinity of this angular frequency.

In the present embodiment, since the second local signal source 1007 is connected, IMD2 is also generated in this region. This IMD2 is the angular frequency shown in FIG. 3B, and it is possible to reduce distortion by setting this angular frequency to the same angular frequency as IMD3 and reversing the phase by 180 degrees. For example, under the condition that the angular frequency No. 1 in FIG. 3A and the angular frequency No. 3 in FIG. 3B are the same, that is, ω _LO2 = 2ω _LO1 -ω _IF1 , φ _LO2 -φ _LO1 Therefore, it is possible to reverse the phases of the two signals by adjusting the phase of the previous phase shifter 1006. On the other hand, the distortion is minimized at the point where the following expression (6) is satisfied.

These A _M , A _MI , A _D , and A _DI can be calculated as shown in equations (4) to (7).

Substituting into this equation (6), the output amplitude B ₂ of the second local signal source 1007 and the output amplitude B ₁ of the first local signal source 1001, the signal amplitude A inputted from a transmission signal input terminal 1000 It can be calculated as the following equation (8) as a function.

Equation (8) means that there is an optimum value for minimizing distortion in the amplitude B ₂ of the local signal source 1007 in accordance with the signal amplitude from the transmission signal input terminal 1000. However, in general, since the amplitudes B ₁ and B ₂ of the local signal sources 1001 and 1007 do not change according to the signal amplitude of the transmission signal source, the equation (8) is the signal amplitude input from the transmission signal input terminal 1000. It shows that IMD3 is minimized at a certain value. FIG. 4 shows a result of actually calculating the distortion reduction effect according to the first embodiment. The horizontal axis of FIG. 4 represents the signal amplitude input from the transmission signal input terminal 1000. The vertical axis in FIG. 4 is the value of IMD3. Even if distortion is reduced at a specific output amplitude, distortion can be reduced in the vicinity of the amplitude, so the distortion is minimal at the point where the generated IMD2 and the original IMD3 are almost the same, and around ± 2 dB around it. It turns out that it is improving rather than the original distortion.

What is calculated as an example is a case where the angular frequency No. 1 in FIG. 3A and the angular frequency No. 1 in FIG. 3B are cancelled, and it is possible to freely select which combination cancels the IMD3. Therefore, the signal angular frequency of the second local signal source can be selected from 2ω _LO1 ± ω _IF1 , 2ω _LO1 ± ω _IF2 , 2ω _LO1 ± 3ω _IF1 , 2ω _LO1 ± 3ω _{IF2, and the} like. Note that ω _IF1 and ω _IF2 are one of the angular frequencies of the signal input to the transmission signal input terminal 1000. _Therefore , when generalized, the subscripts 1 and 2 are removed and expressed as ω _IF . That is, 2ω _LO1 ± ω _IF or 2ω _LO1 ± 3ω _IF can be selected as the signal angular frequency of the second local signal source. Further, even if the first local signal and the second local signal are interchanged, the amplitudes B ₁ and B ₂ and the phases φ _LO1 and φ _LO2 are merely interchanged in the above formula, and the effect of this embodiment is not lost. . Even when the transmission signal is a modulated wave, as described in Non-Patent Document 1, since the generation factors of IMD3 and ACPR (ACLR) are the same, an ACPR reduction effect can be obtained. As described above, by using the first embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

(Second embodiment)
FIG. 5 is a block diagram showing a second embodiment of the present invention. In FIG. 5, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 is connected to the signal synthesizer via the phase shifter 1006 that adjusts the phase of the signal. Connected to the second input terminal of 1005. The mixer 1002 is an element having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the signal to the output terminal. The mixer 1002 transmits the signal to the first input terminal of the mixer 1002. The signal from the signal input terminal 1000 is input, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer 1002. The output terminal of the mixer is connected to the input terminal of the amplifier 1003 via the low-pass filter 1008, and the output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the second local signal source has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

The low-pass filter 1008 connected to the output of the mixer 1002 has f _LO1 -f _IF1 , f _LO1 -f _IF2 (image signal), and f _LO1 + f _IF1 , f if the signal frequency of the second local signal is f _{LO2 LO1} + f _IF2 (main signal) is passed with constant loss L ₁ (dB), and f _LO2 -f _IF1 and f _LO2 -f _IF2 signals (second harmonic image) are constant loss L ₂ (dB) And has a characteristic of blocking the signal (double wave) of f _LO2 + f _IF1 and f _LO2 + f _IF2 .

Next, the principle of the operation of the present embodiment will be described with reference to FIGS. The basic operation principle of the second embodiment is the same as that of the first embodiment. The difference is that the second harmonic is blocked by the low-pass filter 1008, and the amplitude of the second harmonic image signal changes due to attenuation. Considering this point, the signal of IMD2 appearing in the vicinity of the two angular frequencies of ω _LO1 + ω _IF1 and ω _LO1 + ω _IF2 which are the main signals is obtained as shown in FIG. 2C. The IMD3 signal is the same except that the value of A in the table of FIG. 3A changes as shown in the following equation (9).

By making the angular frequency of these IMD2 the same as that of IMD3 and reversing the phase by 180 degrees, it is possible to reduce the distortion as in the first embodiment. Further, the attenuation itself of the second harmonic image signal itself affects the amplitude of the second local signal source in the equation (8), but does not affect the basic operation of the present embodiment.
As described above, by using the second embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

(Third embodiment)
FIG. 6 is a block diagram showing a third embodiment of the present invention. In FIG. 6, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 is connected to the signal synthesizer via the phase shifter 1006 that adjusts the phase of the signal. Connected to the second input terminal of 1005. The mixer 1002 is an element having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the signal to the output terminal. The mixer 1002 transmits the signal to the first input terminal of the mixer 1002. The signal from the signal input terminal 1000 is input, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer 1002. The output terminal of the mixer is connected to the input terminal of the amplifier 1003 via the high-pass filter 1009, and the output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the local signal source 2 has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

The high-pass filter 1009 connected to the output of the mixer 1002 blocks f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) when the signal frequency of the second local signal is f _LO2, and f _LO1 + f _IF1 , F _LO1 + f _IF2 (main signal) is passed with a constant loss L ₂ (dB), and f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (double harmonic image) and f _LO2 + f _IF1 , f _LO2 + f _IF2 signal (2nd harmonic) is passed with constant loss L ₁ (dB).

Next, the principle of operation of this embodiment will be described with reference to FIGS. The basic operation principle of the third embodiment is the same as that of the first and second embodiments. The difference is that the image signal is blocked by the high-pass filter 1009 and the amplitude of the main signal is changed due to attenuation. Considering this point, the signal of IMD2 appearing in the vicinity of the two angular frequencies of ω _LO1 + ω _IF1 and ω _LO1 + ω _IF2 which are the main signals is obtained as shown in FIG. 2D. The IMD3 signal is the same except that the value of A in the table of FIG. 3A changes as shown in equation (10).

  By making the angular frequency of these IMD2 the same as that of IMD3 and reversing the phase by 180 degrees, it is possible to reduce distortion as in the first and second embodiments. Further, the attenuation itself of the second harmonic image signal itself affects the amplitude of the second local signal source in the equation (8), but does not affect the basic operation of the present embodiment. As described above, by using the third embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

(Fourth embodiment)
FIG. 7 is a block diagram showing a fourth embodiment of the present invention. In FIG. 7, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 is connected to the signal synthesizer via the phase shifter 1006 that adjusts the phase of the signal. Connected to the second input terminal of 1005. The mixer 1002 is an element having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the signal to the output terminal. The mixer 1002 transmits the signal to the first input terminal of the mixer 1002. The signal from the signal input terminal 1000 is input, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer 1002. The output terminal of the mixer is connected to the input terminal of the amplifier 1003 via the band pass filter 1010, and the output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the local signal source 2 has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

The band-pass filter 1010 connected to the output of the mixer 1002 blocks f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) and _sets f _LO1 + f when the signal frequency of the second local signal is f _LO2. Pass _IF1 and f _LO1 + f _IF2 (main signal) with constant loss L ₁ (dB), and let f _LO2 -f _IF1 and f _LO2 -f _IF2 signals (double wave image) have constant loss L ₂ It has the characteristic of passing through (dB) and blocking the f _LO2 + f _IF1 and f _LO2 + f _IF2 signals (double wave).

Next, the principle of operation of the present embodiment will be described with reference to FIGS. The basic operation principle of the fourth embodiment is the same as that of the first to third embodiments. The difference is that the band-pass filter 1010 blocks the image signal and the second harmonic, and the amplitude of the main signal and the second harmonic image changes due to attenuation. Considering this point, the signal of IMD2 appearing in the vicinity of the two angular frequencies of ω _LO1 + ω _IF1 and ω _LO1 + ω _IF2 as main signals is obtained as shown in FIG. 2E. The IMD3 signal is the same except that the value of A in the table of FIG. 3A changes as shown in the following equation (11).

  By making the angular frequency of these IMD2 the same as that of IMD3 and reversing the phase by 180 degrees, it is possible to reduce distortion as in the first to third embodiments. Further, the attenuation itself of the second harmonic image signal itself affects the amplitude of the second local signal source in the equation (8), but does not affect the basic operation of the present embodiment. As described above, by using the fourth embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

(Fifth embodiment)
FIG. 8 is a block diagram showing a fifth embodiment of the present invention. In FIG. 8, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 is connected to the signal synthesizer via the phase shifter 1006 that adjusts the phase of the signal. Connected to the second input terminal of 1005. The mixer block 1014 is an element having a function of suppressing the image signal by mixing the signal from the first input terminal of the mixer block and the signal from the second input terminal and outputting the mixed signal to the output terminal. The signal from the transmission signal input terminal 1000 is input to the first input terminal, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer block 1014. The output terminal of the mixer block is connected to the input terminal of the amplifier 1003, and the output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the second local signal source has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

  As described above, the mixer block 1014 is a mixer that suppresses an image signal, and shows a configuration within a dotted line 1014 in FIG. 8 as an example of the configuration. The input signal from the transmission signal input terminal 1000 branches into two paths, one of which is input to the first input terminal of the first mixer 1015 via the 90 degree phase shifter 1011 and the other is the second Is input to the second input terminal of the mixer 1016. The local signal output from the signal synthesizer 1005 is also distributed to two paths, one of which is input to the first mixer 1015 via the 90 degree phase shifter 1013 and the other is input to the second mixer 1016. The outputs of the first and second mixers are output via a signal synthesizer 1012. The first and second mixers 1015 and 1016 are elements having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the result to the output terminal.

This mixer block suppresses the image signal from the output signal. As a result, if the signal frequency of the second local signal is f _LO2 , the signals of f _LO1 + f _IF1 and f _LO1 + f _IF2 (main signal) and the signals of f _LO2 + f _IF1 and f _LO2 + f _IF2 ( 2nd harmonic signal) is output, f _LO1 -f _IF1 , f _LO1 -f _IF2 signal (image signal), and f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (2nd harmonic image signal) Is suppressed.

Next, the principle of operation of the present embodiment will be described with reference to FIGS. The basic operation principle of the fifth embodiment is the same as that of the first to fourth embodiments. The difference is that the mixer block 1014 suppresses the image signal and the second harmonic image. Considering this point, the signal of IMD2 appearing in the vicinity of the two angular frequencies of ω _LO1 + ω _IF1 and ω _LO1 + ω _IF2 which are main signals is obtained as shown in FIG. 2F. The IMD3 signal is the same except that the value of A in the table of FIG. 3A changes as shown in the following equation (12).

  By making the angular frequency of these IMD2 the same as that of IMD3 and reversing the phase by 180 degrees, it is possible to reduce distortion as in the first to fourth embodiments. As described above, by using the fifth embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

(Sixth embodiment)
9, 10 and 11 are block diagrams showing a sixth embodiment of the present invention. In FIGS. 9, 10, and 11, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 includes a phase shifter 1006 that adjusts the phase of the signal. To the second input terminal of the signal synthesizer 1005. The mixer 1002 is an element having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the signal to the output terminal. The mixer 1002 transmits the signal to the first input terminal of the mixer 1002. The signal from the signal input terminal 1000 is input, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer 1002. The output terminal of the mixer is connected to the input terminal of the amplifier 1003 via a filter whose amount of attenuation can be variably adjusted (a low-pass filter 1019 in FIG. 9, a high-pass filter 1020 in FIG. 10, and a band-pass filter 1021 in FIG. 11). The output terminal 1003 is connected to the output terminal 1004 of the entire circuit. A detector 1017 is connected between the transmission signal input terminal 1000 and the mixer 1002, and the output of the detector 1017 is connected to the attenuation control terminals of the filters 1019, 1020, and 1021 via the signal processing unit 1018.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the second local signal source has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

A filter connected to the output of the mixer 1002 (the low-pass filter 1019 in FIG. 9, the high-pass filter 1020 in FIG. 10, and the band-pass filter 1021 in FIG. 11) has the following frequency as f _LO2 : It has various characteristics.

In the case of the low-pass filter of FIG. 9, as in the second embodiment, f _LO1 -f _IF1 , f _LO1 -f _IF2 (image signal), f _LO1 + f _IF1 , f _LO1 + f _IF2 (main signal) passed at a constant loss L ₁ (dB), is passed through f _LO2 -f _IF1, f _LO2 of -f _IF2 signal (second harmonic images) at a constant loss _{L 2 (dB), f LO2} + f IF1 , F _LO2 + f _IF2 signal (second harmonic) is cut off, and this loss L ₂ (dB) can be controlled by an attenuation control terminal.

In the case of the high-pass filter in FIG. 10, as in the third embodiment, f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) are blocked and f _LO1 + f _IF1 and f _LO1 + f _IF2 (main Signal) with a constant loss L ₂ (dB), f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (double wave image) and f _LO2 + f _IF1 , f _LO2 + f _IF2 signal ( 2nd harmonic) with a constant loss L ₁ (dB), and this loss L ₂ (dB) can be controlled by an attenuation control terminal.

In the case of the bandpass filter of FIG. 11, as in the fourth embodiment, f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) are blocked and f _LO1 + f _IF1 and f _LO1 + f _IF2 ( The main signal is passed with a constant loss L ₁ (dB), and the f _LO2 -f _IF1 and f _LO2 -f _IF2 signals (second harmonic image) are passed with a constant loss L ₂ (dB). _LO2 + f _IF1 and f _LO2 + f _IF2 signals (second harmonic) are cut off, and this loss L ₂ (dB) can be controlled by an attenuation control terminal.

  Next, the principle of operation of the present embodiment will be described with reference to FIGS. The basic operation principle of the sixth embodiment is the same as that of the second to fourth embodiments. The difference is that the attenuation amount of the filters 1019, 1020, and 1021 is controlled.

  A case where the low pass filter 1019 of FIG. 9 is used will be described. Under this condition, when the process of deriving the expression (8) from the expressions (6) and (7) described in the description of the operation of the first embodiment is calculated, first, the condition of the expression (7) From the characteristic, it is expressed as the following equation (13).

  At this time, the equation (8) is calculated as the following equation (14).

Equation (14) means that the optimum value that minimizes distortion exists in the product of the amplitudes B ₂ and k of the local signal source 1007 according to the signal amplitude input from the transmission signal input terminal 1000. Yes. As described in the explanation of the operation of the first embodiment, the amplitudes B ₁ and B ₂ of the local signal sources 1001 and 1007 are not changed in accordance with the signal amplitude of the transmission signal source, so the equation (14) Indicates that there exists a value of k that minimizes IMD3 according to the signal amplitude input from the transmission signal input terminal 100. That is, the signal processor 1018 in FIG. 9 inputs the signal from the transmission signal input terminal 1000 by controlling the loss L _{2 so} as to satisfy the equation (14) corresponding to the signal amplitude detected by the detector 1017. It is possible to reduce IMD3 without depending on the signal amplitude.

  Although the case of the low-pass filter of FIG. 9 has been described above, the IMD3 can be reduced by the same method even when the high-pass filter of FIG. 10 or the band-pass filter of FIG. 11 is used. As described above, by using the sixth embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

In the sixth embodiment (FIGS. 9, 10, and 11), the conditions of the filter are shown as an example, but the signal (main signal, image of the main signal) that is up-converted by f _LO1 , and f _If the loss of signals (double wave and double wave image) up-converted by _LO2 is different and one of them can be controlled, the same effect as this embodiment can be obtained.

(Seventh embodiment)
12 and 13 are block diagrams showing a seventh embodiment of the present invention. 12 and 13, the first local signal source 1001 is connected to the first input terminal of the signal synthesizer 1005, and the second local signal source 1007 is connected via the phase shifter 1006 that adjusts the phase of the signal. Connected to the second input terminal of the signal synthesizer 1005. The mixer block 1014 is an element having a function of suppressing the image signal by mixing the signal from the first input terminal of the mixer block and the signal from the second input terminal and outputting the mixed signal to the output terminal. The signal from the transmission signal input terminal 1000 is input to the first input terminal, and the output terminal of the signal synthesizer 1005 is connected to the second input terminal of the mixer block 1014. The output terminal of the mixer block is connected to the input terminal of the amplifier 1003 via a filter (the low-pass filter 1019 in FIG. 12 and the high-pass filter 1020 in FIG. 13), and the output terminal of the amplifier 1003 is connected to the output terminal 1004 of the entire circuit. . A detector 1017 is connected between the transmission signal input terminal 1000 and the mixer block 1014, and the output of the detector 1017 is connected to the attenuation control terminals of the filters 1019 and 1020 via the signal processing unit 1018.

When the first local signal source 1001 and the second local signal source 1007 have the signal frequency of the first local signal source as f ₀ and the signal frequency input from the transmission signal input terminal 1000 as f _IF , The signal frequency of the local signal source 2 has a relationship of 2f ₀ ± f _IF . Alternatively, the signal frequency of the first local signal source and the signal frequency of the second local signal source may be reversed.

  As described above, the mixer block 1014 is a mixer that suppresses an image signal, and shows a configuration within a dotted line 1014 in FIG. 8 as an example of the configuration. The input signal from the transmission signal input terminal 1000 branches into two paths, one of which is input to the first input terminal of the first mixer 1015 via the 90 degree phase shifter 1011 and the other is the second Is input to the second input terminal of the mixer 1016. The local signal output from the signal synthesizer 1005 is also distributed to two paths, one of which is input to the first mixer 1015 via the 90 degree phase shifter 1013 and the other is input to the second mixer 1016. The outputs of the first and second mixers are output via a signal synthesizer 1012. The first and second mixers 1015 and 1016 are elements having a function of mixing a signal from the first input terminal of the mixer and a signal from the second input terminal and outputting the result to the output terminal.

This mixer block suppresses the image signal from the output signal. As a result, if the signal frequency of the second local signal is f _LO2 , the signals of f _LO1 + f _IF1 and f _LO1 + f _IF2 (main signal) and the signals of f _LO2 + f _IF1 and f _LO2 + f _IF2 ( 2nd harmonic signal) is output, f _LO1 -f _IF1 , f _LO1 -f _IF2 signal (image signal), and f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (2nd harmonic image signal) Is suppressed.

  Further, the output signal of the mixer block is attenuated by the filter.

In the case of the low-pass filter of FIG. 12, f _LO1 -f _IF1 , f _LO1 -f _IF2 (image signal) and f _LO1 + f _IF1 and f _LO1 + f _IF2 (main signal) are set as in the second embodiment. certain loss passed by L ₁ (dB), is passed through f _LO2 -f _IF1, f _LO2 of -f _IF2 signal (second harmonic images) at a constant loss _{L 2 (dB), f LO2} + f _IF1 and f _LO2 + f _IF2 has a characteristic of blocking the signal (second harmonic), and this loss L ₂ (dB) can be controlled by an attenuation control terminal.

In the case of the high-pass filter of FIG. 13, as in the third embodiment, f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signals) are blocked and f _LO1 + f _IF1 and f _LO1 + f _IF2 (main Signal) with a constant loss L ₂ (dB), f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (double wave image) and f _LO2 + f _IF1 , f _LO2 + f _IF2 signal ( 2nd harmonic) with a constant loss L ₁ (dB), and this loss L ₂ (dB) can be controlled by an attenuation control terminal.

In the case of Fig. 12, f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) are suppressed, and f _LO1 + f _IF1 and f _LO1 + f _IF2 (main signal) are constant. Loss, passing through L ₁ (dB), f _LO2 -f _IF1 , f _LO2 -f _IF2 signal (second harmonic image) passes with a constant loss L ₂ (dB), f _LO2 + f _IF1 , The f _LO2 + f _IF2 signal (second harmonic) is suppressed. In the case of FIG. 13, f _LO1 -f _IF1 and f _LO1 -f _IF2 (image signal) are suppressed, f _LO1 + f _IF1 and f _LO1 + f _IF2 (main signal) are constant loss, L ₂ (dB ) And f _LO2 -f _IF1 and f _LO2 -f _IF2 signals (second harmonic image) pass with a constant loss L ₁ (dB), and f _LO2 + f _IF1 and f _LO2 + f _IF2 The signal (second harmonic) is suppressed.

  Next, the principle of operation of the present embodiment will be described with reference to FIG. The basic operation principle of the seventh embodiment is the same as that of the fifth embodiment. The difference is that the output power of the main signal and the second harmonic is different by the filters 1019 and 1020, and the attenuation amount is controlled.

  A case where the low-pass filter 1019 of FIG. 12 is used will be described. Under this condition, when the process of deriving the expression (8) from the expressions (6) and (7) described in the description of the operation of the first embodiment is calculated, first, the condition of the expression (7) It is expressed as shown in equation (15) from the characteristics of

  At this time, equation (8) is calculated as equation (16).

Equation (16) means that the optimum value that minimizes distortion exists in the product of the amplitudes B ₂ and k of the local signal source 1007 according to the signal amplitude input from the transmission signal input terminal 1000. Yes. As described in the explanation of the operation of the first embodiment, the amplitudes B ₁ and B ₂ of the local signal sources 1001 and 1007 are not changed according to the signal amplitude of the transmission signal source. Indicates that there exists a value of k that minimizes the IMD3 distortion in accordance with the signal amplitude input from the transmission signal input terminal. In other words, the signal processing section 1018 in FIG. 12, in response to the signal amplitude detected by the detector 1017 is input since a transmission signal input terminal 1000 for controlling the loss L ₂ so as to satisfy the equation (16) It is possible to reduce IMD3 without depending on the signal amplitude.

  Although the case of the low-pass filter of FIG. 12 has been described above, the IMD3 can be reduced by the same method in the high-pass filter of FIG. As described above, by using the seventh embodiment, an effect of reducing IMD3 or ACPR (ACLR) can be obtained.

  In the embodiment of the present embodiment described above, two local signals are used and one generated IMD3 is canceled and reduced. However, three or more local signals are used to reduce distortion of individual angular frequencies. It is also possible to reduce.

  Further, the block diagrams (FIG. 1, FIG. 5 to FIG. 13) of the embodiment of the present embodiment include only the minimum elements necessary for the operation of the embodiment. In actual operation of a wireless communication device, in addition to these elements, elements such as a mixer (including a modulator), an amplifier, a filter, an attenuator, and a switch may be used.

(Appendix 1)
A non-linear amplifier having a mixer that up-converts to a frequency of f _LO + f _IF using a transmission input signal (frequency f _IF ) and a first local signal (frequency is f _LO ), and amplifies the up-converted signal In a wireless communication device having
A second local signal having a frequency of 2f _LO ± f _IF or 2f _LO ± 3f _IF is added to the first local signal input to the mixer,
A wireless communication apparatus having a distortion reduction function.
(Appendix 2)
In a wireless communication apparatus having an amplifier that generates distortion due to nonlinearity,
By adding a signal of another frequency to a signal of a frequency used for communication by the wireless communication device and inputting the signal to the nonlinear amplifier,
A third-order distortion generated from a signal having a frequency used for communication and a second-order distortion generated from a signal having a frequency used for communication and a signal having another frequency cancel each other. Distortion reduction technique.
(Appendix 3)
In the wireless communication device according to attachment 2,
A method for reducing distortion of a wireless communication device, characterized in that the signal of the other frequency is realized by adding an additional signal to a local signal input to a mixer disposed before the nonlinear amplifier.
(Appendix 4)
In the wireless communication device according to attachment 1,
A radio communication apparatus having a distortion reduction function, wherein the up-converting mixer is a mixer that suppresses an image signal.
(Appendix 5)
In the wireless communication device according to attachment 1,
A wireless communication apparatus having a distortion reducing function, wherein a low-pass filter that passes a frequency f _LO + f _IF and blocks a frequency f _LO -f _IF is added between a mixer and a nonlinear amplifier.
(Appendix 6)
In the wireless communication device according to attachment 4,
A wireless communication apparatus having a distortion reducing function, wherein a low-pass filter that passes a frequency f _LO + f _IF and blocks a frequency f _LO -f _IF is added between a mixer and a nonlinear amplifier.
(Appendix 7)
In the wireless communication device according to appendix 1, or appendix 4, or appendix 5,
When the frequency of the second local signal is f _LO2 ,
Between the mixer and the non-linear amplifier is passed through a frequency f _LO2 -f _IF, radio communication apparatus having a distortion reduction function, characterized in that adding a high-pass filter that blocks frequencies f _{LO2 +} f _IF.
(Appendix 8)
In the wireless communication device according to appendices 5 to 6,
A distortion reduction function characterized in that the filter can control a passage loss of either a signal up-converted by the first local signal or a signal up-converted by the second local signal. A wireless communication device.
(Appendix 9)
In the wireless communication device according to attachment 8,
A wireless communication apparatus having a distortion reduction function, characterized in that the pass loss of the filter is changed according to the amplitude of the transmission input signal.

1000 Transmission signal input terminal
1001 First local signal source
1002, 1015, 1016 mixer
1003 amplifier
1004 Output terminal
1005, 1012 Signal synthesis element
1006 Phaser
1007 Second local signal source
1008 Low pass filter
1009 High pass filter
1010 Bandpass filter
1011, 1013 90 degree phase shifter
1014 Mixer block
1017 detector
1018 Signal processor
1019 Variable attenuation low pass filter
1020 Variable attenuation high-pass filter
1021 Band-pass filter with variable attenuation
IMD3 generated from 1200 amplifier
1201 IMD2 generated from an amplifier
1202 IMD3 in the first embodiment

Claims (6)

A first local oscillator that outputs a first local signal at a first local frequency f _LO1 ;
A second local oscillator for outputting a second local signal having a second local frequency f _LO2 ;
An adder for adding the first local signal and the second local signal;
Using the output signal of the adder, a mixer that up-converts a transmission input signal having a frequency of f _IF ,
An amplifier for amplifying the output signal of the mixer;
With
The second local frequency f _LO2 is set to 2f _LO1 ± f _IF or 2f _LO1 ± 3f _IF .
Distortion reduction circuit. The distortion reduction circuit according to claim 1,
The mixer is configured to suppress an image signal included in the output signal of the mixer.
Distortion reduction circuit. The distortion reduction circuit according to claim 1 or 2,
Between the mixer and the amplifier,
A low-pass filter that passes a signal having a frequency of f _LO1 + f _IF among the output signals of the mixer and blocks a signal having a frequency of f _LO1 -f _IF among the output signals of the mixer;
Distortion reduction circuit. The distortion reduction circuit according to claim 1 or 2,
Between the mixer and the amplifier,
A signal having a frequency of f _LO2 −f _IF among the output signals of the mixer is allowed to pass; and a signal having a frequency of f _LO2 + f _IF among the output signals of the mixer is further cut off.
Distortion reduction circuit. The distortion reduction circuit according to claim 3 or 4,
The low-pass filter or the high-pass filter is
It is configured to be able to control the passage loss of either one of the signal upgraded by the mixer using the first local signal and the signal upgraded by the mixer using the second local signal. ing,
Distortion reduction circuit. The distortion reduction circuit according to claim 5,
The low-pass filter or the high-pass filter is
Controlling the passage loss based on the amplitude of the transmission input signal;
Distortion reduction circuit.

Images