JP2002176321A - Method for correcting distortion of transmission signal in radio equipment and radio equipment having distortion correction function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a distortion correcting method capable of maintaining a constant transmission distortion characteristic with respect to the change of the transmission distortion characteristic caused by environmental variation, etc., and radio equipment having a distortion correction function. SOLUTION: Baseband data 10 to be transmitted is converted into a transmission signal through a distortion compensating part 117, a D/A converting part 102, an orthogonal modulator 103 and a frequency converter 104, subjected to power amplification in a power amplifier 105 and outputted from an antenna part 107. A part of the output 17 of the power amplifier 105 is digitally converted into feedback system baseband data 21 through a directional coupler 106, a frequency converter 113, a quadrature demodulator 112 and an A/D converting part 111. The feedback system baseband data 21 is compared with the baseband data 10 to be transmitted by a comparing part 115, and a distortion quantity operating part 114 calculates the distortion quantity of the transmission signal. A bias controlling part 110 controls the bias voltage of the power amplifier 105 on the basis of the distortion quantity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a radio apparatus having a function of correcting distortion of a nonlinear power amplifier and a method of correcting distortion.

[0002]

2. Description of the Related Art A radio apparatus having a distortion compensation circuit for canceling transmission distortion due to a nonlinear characteristic of a power amplifier is known.
As typical distortion compensation methods for feeding back a part of the output of a power amplifier using a directional coupler or the like, an adaptive predistortion method and a Cartesian feedback method are known. The former adds a configuration for monitoring a feedback signal and adaptively changing the inverse characteristic data to a predistortion system for transmitting a baseband signal corrected in advance by inverse characteristic data for canceling a distortion characteristic of a power amplifier. This is a method for following changes in the characteristics of the power amplifier. The latter is a method in which a difference (distortion) between the transmitted baseband signal and the feedback signal is combined with the transmitted baseband signal to form a loop and cancel the distortion of the power amplifier. In any of the above-described distortion compensation methods, the signal output from the power amplifier is fed back, and the transmitted baseband signal adaptively follows the change in the distortion characteristic of the power amplifier. The amount of compensation has changed.

[0003] The nonlinearity of a power amplifier largely depends on the current consumption determined by the bias applied to the power amplifier. Generally, the higher the current consumption, the better the distortion characteristics of the power amplifier. Further, the non-linearity changes due to environmental fluctuations such as operating temperature and power supply voltage. Therefore, the current consumption of the power amplifier is usually set to a value larger than the minimum current value for performing distortion compensation, with a certain margin, in consideration of the above-described environmental fluctuation and characteristic variations of the power amplifier. It is. However, in a general wireless device, the current consumption of the power amplifier occupies a large proportion of the current consumption of the entire device. Therefore, in a portable device using a storage battery, the current consumption of the power amplifier cannot be sufficiently increased.

When the current consumption of the power amplifier is fixed, and when the characteristics of the element change due to environmental changes such as operating temperature and power supply voltage, adjacent channel leakage power and carrier power change. Affects performance. In response to these two fluctuations, the adaptive predistortion method maintains the distortion compensation effect by means such as adaptively changing the inverse distortion characteristic table to prevent the adjacent channel leakage power from deteriorating, and the gain of the distortion compensation loop. Is changed to a preset value to correct the transmission output to prevent fluctuation of the transmission power.

In the Cartesian feedback system, since the distortion compensating circuit is a closed loop due to the circuit configuration, it is possible to change the amount of distortion compensation by following the fluctuation of the adjacent channel leakage power due to a change in element characteristics. it can. As for the fluctuation of the transmission power, there is a method of changing the gain of the distortion compensation loop to a preset value and correcting the transmission output to prevent the fluctuation of the transmission power as in the case of the adaptive predistortion method.

As described above, with respect to the fluctuation of the transmission power caused by the characteristic change of the element due to the environmental fluctuation or the like, in any of the above-described distortion compensation methods, an experiment is performed in advance by considering the transmission performance such as the adjacent channel leakage power. In this case, a correction is made using a value obtained as a result or a value obtained by predicting a characteristic variation based on measured characteristic data of the element.

[0007]

However, the transmission power of the power amplifier and the distortion characteristics such as the adjacent channel leakage power are in an inverse relationship, and the transmission distortion characteristics deteriorate (the amount of distortion compensation increases) as the transmission power increases. If the transmission power decreases, the distortion characteristic improves (the distortion compensation amount decreases). Therefore, if the transmission power deviates from the amount of fluctuation predicted in advance, there is a possibility that transmission distortion performance will be greatly affected. .

An object of the present invention is to provide a distortion correction method and a radio apparatus having a distortion correction function capable of maintaining a constant transmission distortion characteristic with respect to a change in transmission distortion characteristics due to environmental fluctuations and the like. .

[0009]

SUMMARY OF THE INVENTION The present invention corrects distortion of a transmission signal in a radio apparatus that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data by an amplifier. The feedback baseband data obtained by extracting and demodulating a part of the output of the amplifier, based on a comparison result of the baseband data, to determine the amount of distortion of the transmission signal, the obtained amount of distortion The bias voltage of the amplifier is changed accordingly. Therefore, when the amount of distortion exceeds a prescribed value, it is possible to adaptively prevent deterioration of transmission distortion characteristics due to nonlinearity of the power amplifier by increasing current consumption.

According to the obtained distortion amount, the amplitude value of the baseband data is increased or decreased, or the amplitude value of the feedback baseband data is increased or decreased, or the feedback gain of a part of the output of the amplifier is changed. It is to increase or decrease.
Therefore, when the amount of distortion exceeds a predetermined value, the output power of the power amplifier is reduced, and it is possible to adaptively prevent the transmission distortion characteristic from deteriorating due to the nonlinearity of the power amplifier.

[0011] The baseband data is subjected to adaptive predistortion type distortion compensation.

[0012] The present invention also corrects distortion of a transmission signal in a radio apparatus that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data by an amplifier. A feedback baseband signal obtained by extracting and demodulating a part of the baseband signal, a distortion amount of the transmission signal is determined based on a comparison result with the baseband signal, and the amplifier of the amplifier is determined according to the determined distortion amount. This is to change the bias voltage.
Therefore, when the amount of distortion exceeds a prescribed value, it is possible to adaptively prevent deterioration of transmission distortion characteristics due to nonlinearity of the power amplifier by increasing current consumption.

Further, the amplitude value of the baseband data is increased or decreased, or the feedback gain of a part of the output of the amplifier is increased or decreased according to the obtained distortion amount. Therefore, when the amount of distortion exceeds a predetermined value, the output power of the power amplifier is reduced, and it is possible to adaptively prevent the transmission distortion characteristic from deteriorating due to the nonlinearity of the power amplifier.

The baseband signal is a signal subjected to a distortion compensation of a Cartesian feedback system.

Further, the baseband data has been subjected to adaptive predistortion type distortion compensation.

[0016]

Embodiments of the present invention will be described with reference to the drawings.

(First Embodiment) FIG. 1 shows a first embodiment of the present invention.
1 is a diagram illustrating a schematic configuration of an embodiment of the present invention, and illustrates a transmission unit of a wireless device including a distortion compensation circuit of an adaptive predistortion method.

In the radio apparatus of FIG. 1, baseband data 10 to be transmitted is subjected to adaptive pre-distortion type distortion compensation processing in a distortion compensating section 117 of an arithmetic / control section 1 comprising a DSP, and is subjected to inverse distortion. It is converted into characteristic baseband data 11. This distortion compensation processing is performed by storing an initial table of baseband data having an inverse distortion characteristic that cancels nonlinear distortion generated in the transmission unit of the wireless device, particularly, the power amplifier 105, which is stored in a memory unit (not shown) in advance. Processing for generating a distortion compensation table (not shown) by using the processing, a distortion amount calculation unit 114 and a compensation coefficient calculation unit 11 described later.
6 includes a process of updating the distortion compensation table in accordance with the distortion compensation coefficient 22 determined by 6 and a process of generating the inverse distortion characteristic baseband data 11 using the updated distortion compensation table.

The inverse distortion characteristic baseband data 11 is represented by D /
The analog signal is converted into an in-phase (I) component and a quadrature (Q) component by an A conversion unit 102, and is input to a quadrature modulator 103 as a transmission system baseband signal 12. Quadrature modulator 103
Then, a local signal 13 input from a local oscillator 108 is orthogonally modulated by the transmission system baseband signal 12 and output as an intermediate frequency signal 14. The output intermediate frequency signal 14 is input to the frequency converter 104, and the frequency is converted to a desired carrier signal 16 by the local signal 15 input from the local oscillator 109. The carrier signal 16 is power-amplified by the power amplifier 105 and output from the antenna unit 107.

The feedback signal 18 obtained by extracting a part of the output 17 of the power amplifier 105 by the directional coupler 106 is input to the frequency converter 113, and the intermediate frequency signal 19 is output by the local signal 15 input from the local oscillator 109.
Is frequency-converted. The intermediate frequency signal 19 is input to a quadrature demodulator 112 and quadrature-demodulated into a feedback baseband signal 20 of I and Q components using a local signal 13 input from a local oscillator 108.
1 is digitally converted into feedback baseband data 21.

The feedback system baseband data 21 and the baseband data 10 to be transmitted are calculated by the arithmetic and control unit 1 at any time.
Are compared by the comparison unit 115, and the distortion amount calculation unit 114 calculates the distortion amount of the transmission signal based on the comparison data 23. When the transmission distortion characteristic of the wireless device changes (due to the nonlinearity of the power amplifier) due to environmental fluctuations such as operating temperature and power supply voltage, the amount of distortion increases or decreases. Since the transmission distortion performance degradation such as an increase in leakage power is indicated, the inverse distortion characteristic baseband data 11
This means that the distortion compensation effect due to is reduced. The compensation coefficient calculation unit 116 calculates the compensation coefficient 22 such that the amount of increasing / decreasing distortion is maintained at a constant value in order to maintain a constant transmission distortion performance, and adaptively updates the distortion compensation table.

However, in the above-mentioned adaptive predistortion loop, if the compensation coefficient increases to some extent, it becomes impossible to compensate for the transmission distortion characteristic of the radio apparatus only by updating the distortion compensation table. Therefore, in the present embodiment, when the transmission distortion characteristic has deteriorated to a certain degree or more, the distortion amount calculation unit 114 of the calculation / control unit 1
Control the bias control unit 110 of the power amplifier 105 to increase the current consumption of the power amplifier 105 to improve the non-linear characteristic of the power amplifier 105 so that the compensation coefficient does not exceed a specified value. Control.

On the other hand, when the compensation coefficient is small, the non-linear characteristic of power amplifier 105 is sufficiently compensated, and the current consumption of power amplifier 1 is excessively increased to a current value at which a specified distortion compensation effect can be obtained. To indicate that Therefore, when the transmission distortion characteristic is sufficiently good, the current consumption of the power amplifier 105 is reduced by controlling the bias control unit 110 with the output 23 from the distortion amount calculation unit 114.
Increase the compensation factor to a specified value. With this control, the current consumption of the power amplifier 105 is set to the minimum value at which a desired distortion compensation effect can be obtained, and power saving control of the wireless device becomes possible.

(Second Embodiment) In a second embodiment of the present invention, similarly to the first embodiment, the value is obtained based on a comparison result between feedback baseband data and baseband data to be transmitted. In addition, the amount of distortion of the transmission signal is used. FIG. 2 is a diagram showing a schematic configuration of a second embodiment of the present invention, and has a distortion compensating circuit of an adaptive pre-distortion system as in FIG. In the second embodiment, the transmission power output from the power amplifier is controlled.

In FIG. 2, the same reference numerals as those in FIG. 1 denote the same elements, and a description thereof will not be repeated. A major difference from FIG. 1 is that the arithmetic and control unit 2 has an amplitude calculating unit 118 and increases or decreases the amplitude value of the baseband data 10 to be transmitted by the output 25 of the distortion amount calculating unit 114. .
The output of the amplitude calculator 118 is sent to the distortion compensator 117 and the comparator 115. Further, the bias control unit 110 for controlling the bias of the power amplifier 105 is not provided.

The wireless device of FIG. 2 also compensates for distortion by using an adaptive predistortion loop. However, when the compensation coefficient increases to some extent, the transmission distortion characteristic of the wireless device can be reduced only by updating the distortion compensation table. I can no longer compensate. Therefore, based on the distortion amount from the distortion amount calculation unit 114, the amplitude calculation unit 118 performs subtraction processing on the amplitude value of the baseband data 10 until the compensation coefficient becomes equal to or less than a specified value. With this control, the transmission power output from the power amplifier 105 decreases, and control can be performed so that the compensation coefficient does not exceed a specified value.

On the other hand, when the compensation coefficient is small, the nonlinear characteristic of the power amplifier 105 is sufficiently compensated, and the transmission power output from the power amplifier 105 is the maximum transmission power that can ensure the transmission distortion performance of the radio apparatus. It indicates that the power is low. Therefore, amplitude calculating section 118 increases the amplitude value of baseband data 10 to increase the transmission power output from power amplifier 105. As described above, in the second embodiment, it is possible to control the maximum transmission power while ensuring transmission distortion performance.

(Third Embodiment) In the third embodiment of the present invention, similarly to the first and second embodiments, the comparison result between the feedback baseband data and the baseband data to be transmitted is obtained. This is to use the amount of distortion of the transmission signal obtained based on this. FIG. 3 is a diagram showing a schematic configuration of a third embodiment of the present invention, and has a distortion compensating circuit of an adaptive pre-distortion system, similarly to FIGS. Further, similarly to the second embodiment, the transmission power output from the power amplifier is controlled.

In FIG. 3, the same reference numerals as those in FIG. 1 denote the same elements, and a description thereof will not be repeated. 1 is that the arithmetic and control unit 3 has an amplitude control unit 119 and increases or decreases the amplitude value of the feedback baseband data 21. The output of the amplitude control unit 119 is
Sent to Further, the bias control unit 110 for controlling the bias of the power amplifier 105 is not provided.

In the radio apparatus shown in FIG. 3, if the transmission distortion characteristics of the radio apparatus cannot be compensated for only by updating the distortion compensation table, the amplitude control section 119 uses the feedback system in the amplitude control section 119 based on the distortion amount from the distortion amount calculation section 114. Subtraction processing is performed on the amplitude value of the baseband data 21 until the compensation coefficient becomes equal to or less than a specified value. With this control, the transmission power output from the power amplifier 105 decreases, and control can be performed so that the compensation coefficient does not exceed a specified value.

When the compensation coefficient is small, the amplitude value of the feedback baseband data 21 is increased, and the power amplifier 105
The transmission power output from is increased. As mentioned above,
In the third embodiment, it is possible to control the maximum transmission power while securing the transmission distortion performance.

(Fourth Embodiment) In the third embodiment of the present invention, similarly to the first to third embodiments, the comparison result between the feedback baseband data and the baseband data to be transmitted is obtained. This is to use the amount of distortion of the transmission signal obtained based on this. FIG. 4 is a diagram showing a schematic configuration of a fourth embodiment of the present invention, and has a distortion compensating circuit of an adaptive pre-distortion system, similarly to FIGS. Also, as in the second and third embodiments,
It controls the transmission power output from the power amplifier.

In FIG. 4, the same reference numerals as those in FIG. 1 indicate the same elements, and the description will be omitted. 1 differs from that of FIG. 1 in that a variable gain amplifier 120 for controlling the gain of the feedback signal 18 is provided. The gain of 120 is controlled to increase or decrease the amplitude value of the feedback baseband data 21. Further, the bias control unit 110 for controlling the bias of the power amplifier 105 is not provided. Furthermore, since no intermediate frequency signal is used,
Frequency converters 104 and 113, local oscillator 109
Has been omitted.

In the wireless device of FIG. 4 as well, if the transmission distortion characteristics of the wireless device cannot be compensated for only by updating the distortion compensation table, the gain of the variable gain amplifier 120 is By controlling the adjustment voltage, the amplitude of the feedback baseband data is increased, and the transmission power is reduced so that the compensation coefficient does not exceed a specified value.

When the compensation coefficient is small, the power amplifier 10
5 is the same as in the second and third embodiments in that the transmission power output from 5 is increased. As described above, also in the fourth embodiment, it is possible to control the maximum transmission power while securing the transmission distortion performance.

(Fifth Embodiment) FIG. 5 is a diagram showing a schematic configuration of a fifth embodiment of the present invention, in which the transmission of a radio apparatus having a distortion compensation circuit of the Cartesian feedback system is performed. Indicates a part.

In the radio apparatus shown in FIG. 5, baseband data 10 to be transmitted is subjected to adaptive pre-distortion type distortion compensation processing in distortion compensation section 219 of arithmetic / control section 5 comprising a DSP, and inverse distortion is applied. It is converted into characteristic baseband data 51. This distortion compensation is performed using a distortion compensation table (not shown) as in the case of FIG. 1, but is not always necessary and can be omitted. Also,
The distortion compensation table is updated based on an output 64 obtained by converting the distortion compensation amount 63 described later by the A / D converter 214.

The inverse distortion characteristic baseband data 51 is D / D
The A-conversion unit 202 performs analog conversion on the in-phase (I) and quadrature (Q) components, respectively, and outputs the result as a transmission system baseband signal 52. A distortion compensation amount 63 extracted by comparison with a feedback system baseband signal 61 described later is added to the transmission system baseband signal 52 and input to the quadrature modulator 204 as a distortion compensation baseband signal 53. In the quadrature modulator 204, the local signal 54 input from the local oscillator 209 is quadrature-modulated by the distortion compensation baseband signal 53 and output as an intermediate frequency signal 55. The output intermediate frequency signal 55 is output from the frequency converter 2
The frequency is converted into a desired carrier signal 57 by the local signal 56 input to the local oscillator 210 and input from the local oscillator 210. The carrier signal 57 is power-amplified by the power amplifier 206 and output from the antenna unit 208.

The feedback signal 59 obtained by extracting a part of the output 58 of the power amplifier 206 by the directional coupler 207 is input to the frequency converter 213, and the intermediate frequency signal 6 is output by the local signal 56 input from the local oscillator 210.
The frequency is converted to 0. The intermediate frequency signal 60 is input to the quadrature demodulator 212, and is quadrature-demodulated into I and Q component feedback baseband signals 61 using the local signal 54 input from the local oscillator 209.

The comparator 215 compares the feedback baseband signal 61 with the transmission baseband signal 52 to extract the distortion compensation amount 63 of the power amplifier 206, and adds the distortion compensation amount 63 to the transmission baseband signal 52 by the adder 203. By doing so, a distortion compensation baseband signal 53 is generated, and a closed loop of distortion compensation is formed. The feedback baseband signal 6
1 is compared with the distortion-compensated baseband signal 53 by the comparator 216 to extract the distortion amount 62. Distortion 62
Approximately shows the amount of distortion compensation for the nonlinear characteristic of the power amplifier 206 in the baseband band. When the transmission distortion characteristic of the wireless device changes due to an environmental change such as an operating temperature or a power supply voltage, the distortion compensation amount 63 increases or decreases.
An increase in the distortion compensation amount 63 indicates a deterioration in transmission distortion performance such as an increase in adjacent channel leakage power of the wireless device. Since the closed loop of the distortion compensation is formed as described above, stability such as causing oscillation is obtained. Will lead to a decline.

However, in the above-described Cartesian feedback loop, if the distortion compensation amount increases to some extent, it becomes impossible to completely compensate for the transmission distortion characteristics of the wireless device. Therefore, in the present embodiment, when the transmission distortion characteristic has deteriorated to a certain degree or more, the power amplifier 20 is output by the output 66 from the distortion amount calculation unit 218 of the calculation / control unit 5.
6 controls the bias control unit 211 to increase the current consumption of the power amplifier 206 to improve the non-linear characteristics of the power amplifier 206 so that the distortion compensation amount 63 does not exceed a specified value. Note that the distortion amount calculation unit 21
8, data obtained by converting the distortion amount 62 by the A / D converter 65 is input.

On the other hand, when the distortion compensation amount 63 is small, the nonlinear characteristic of the power amplifier 206 is sufficiently compensated, and the current consumption of the power amplifier 206 is excessively larger than the current value at which the specified distortion compensation effect can be obtained. Indicates that it is being washed away. Therefore, when the transmission distortion characteristic is sufficiently high, the distortion amount calculation unit 2
The current consumption of the power amplifier 206 is reduced by controlling the bias control unit 211 with the output 66 from 18, and is increased until the distortion amount 62 reaches a specified value. With this control, the current consumption of the power amplifier 206 is set to the minimum value at which a desired distortion compensation effect can be obtained, and power saving control of the wireless device becomes possible.

(Sixth Embodiment) A sixth embodiment of the present invention is also based on a comparison result between a feedback baseband signal 61 and a distortion compensation baseband signal 53, as in the fifth embodiment. In this case, the amount of distortion 62 of the transmission signal, which is obtained as described above, is used. FIG. 6 is a diagram showing a schematic configuration of the sixth embodiment of the present invention, which has a distortion compensation circuit of the Cartesian feedback system. In the sixth embodiment, the transmission power output from the power amplifier is controlled.

6, the same reference numerals as those in FIG. 5 denote the same elements, and a description thereof will not be repeated. 5 is that the arithmetic and control unit 6 has an amplitude calculating unit 220 and increases or decreases the amplitude value of the baseband data 10 to be transmitted by the output 68 of the distortion amount calculating unit 218. .
The output of the amplitude calculator 118 is sent to the distortion compensator 219. Further, a bias control unit 211 for controlling the bias of the power amplifier 206 is not provided.

The radio apparatus shown in FIG. 6 also compensates for distortion using the Cartesian feedback loop. However, if the amount of distortion compensation increases to some extent, the transmission distortion characteristics of the radio apparatus cannot be fully compensated. come. Therefore, based on the distortion amount from the distortion amount calculation unit 218, the amplitude calculation unit 220 subtracts the amplitude value of the baseband data 10 until the distortion compensation amount becomes equal to or less than a specified value. With this control, the transmission power output from the power amplifier 206 decreases, and control can be performed so that the distortion compensation amount does not exceed a specified value.

On the other hand, when the distortion compensation amount is small, the nonlinear characteristic of the power amplifier 206 is sufficiently compensated, and the transmission power output from the power amplifier 206 is the maximum transmission power capable of securing the transmission distortion performance of the radio apparatus. It indicates that the power is low. Therefore, the amplitude value of the baseband data 10 is increased in the amplitude calculation unit 220 and the power amplifier 2
The transmission power output from the control unit 06 is increased. As described above, in the sixth embodiment, it is possible to control the maximum transmission power while securing the transmission distortion performance.

(Seventh Embodiment) In a seventh embodiment of the present invention, similarly to the fifth and sixth embodiments, the feedback baseband signal 61 and the distortion compensation baseband signal 53 are used. The distortion amount 62 of the transmission signal obtained based on the comparison result is used. FIG. 7 is a diagram showing a schematic configuration of the seventh embodiment of the present invention, which has a distortion compensation circuit of the Cartesian feedback system. Further, as in the sixth embodiment, the transmission power output from the power amplifier is controlled.

In FIG. 7, the same reference numerals as those in FIG. 5 indicate the same elements, and the description thereof will be omitted. 5 is different from that of FIG. 5 in that a variable gain amplifier 221 for controlling the gain of the feedback signal 59 is provided. 221 is controlled, and the amplitude value of the feedback baseband data 61 is increased or decreased. Further, a bias control unit 211 for controlling the bias of the power amplifier 206 is not provided. Furthermore, since no intermediate frequency signal is used,
Frequency converters 205 and 213, local oscillator 210
Has been omitted.

In the radio device of FIG. 7 as well, if the transmission distortion characteristics of the radio device cannot be compensated for only by updating the distortion compensation table, the gain of the variable gain amplifier 120 is determined based on the output 66 from the distortion amount calculator 211. By controlling the adjustment voltage, the transmission power is reduced so that the distortion compensation amount does not exceed a specified value.

When the distortion compensation amount is small, the power amplifier 20
6 is the same as the sixth embodiment in that the transmission power output from 6 is increased. As described above, also in the seventh embodiment, it is possible to control the maximum transmission power while securing the transmission distortion performance.

[0051]

As described above, according to the present invention, it is possible to design a power-saving wireless device that adaptively changes the current consumption of the wireless device to a minimum value while maintaining a constant transmission distortion characteristic. Becomes Further, it is possible to design such that the transmission power of the wireless device is adaptively changed to the maximum value while maintaining a constant transmission distortion characteristic.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a schematic configuration according to a second embodiment of the present invention;

FIG. 3 is a diagram showing a schematic configuration of a third embodiment of the present invention;

FIG. 4 is a diagram showing a schematic configuration of a fourth embodiment of the present invention.

FIG. 5 is a diagram showing a schematic configuration of a fifth embodiment of the present invention.

FIG. 6 is a diagram showing a schematic configuration of a sixth embodiment of the present invention.

FIG. 7 is a diagram showing a schematic configuration of a seventh embodiment of the present invention.

[Explanation of symbols]

 1, 2, 3, 4, 5, 6, 7 ... calculation / control unit 102, 202 ... D / A conversion unit 103, 204 ... quadrature modulator 104, 113, 205, 213 ... Frequency converters 105 and 206 Power amplifiers 106 and 207 Directional couplers 107 and 208 Antenna units 108, 109, 209 and 210 Local oscillators 110 and 211 Bias control units 111, 214, 217... A / D conversion units 112, 212... ..Distortion compensating units 118, 220 ... amplitude calculating unit 119 ... amplitude controlling unit 120, 221 ... gain variable amplifier 203 ... adders 215, 216 ... comparators

 ────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Daiji Well 3-1, Tsunashimahigashi, Kohoku-ku, Yokohama-shi, Kanagawa Prefecture F-term (reference) 5J090 AA01 AA41 CA21 CA35 CA36 FA10 FA17 GN03 GN06 KA00 KA17 KA26 KA32. 5K060 BB07 CC04 HH01 HH06

Claims (20)

[Claims] 1. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulation signal obtained by modulating a baseband signal based on baseband data, comprising: Based on the comparison between the feedback baseband data obtained by extracting and demodulating a part and the baseband data, the amount of distortion of the transmission signal is obtained, and the bias of the amplifier is determined according to the obtained amount of distortion. A distortion correction method that changes the voltage. 2. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on variable-amplitude baseband data by an amplifier, The feedback baseband data obtained by extracting and demodulating a part of the output of the baseband data, based on a comparison result of the baseband data, determine the amount of distortion of the transmission signal, according to the determined amount of distortion A distortion correction method for increasing or decreasing the amplitude value of baseband data. 3. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data, comprising: Based on a comparison result between the feedback baseband data obtained by extracting and demodulating a part and the baseband data, a distortion amount of the transmission signal is obtained, and the feedback baseband is obtained according to the obtained distortion amount. A distortion correction method for increasing or decreasing the amplitude value of data. 4. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data, comprising: A feedback baseband data obtained by extracting and demodulating a part thereof, and a distortion amount of the transmission signal are obtained based on a comparison result with the baseband data, and an output of the amplifier is output according to the obtained distortion amount. A distortion correction method that increases or decreases part of the feedback gain. 5. The distortion correction method according to claim 1, wherein the baseband data is subjected to adaptive predistortion type distortion compensation. 6. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data by an amplifier, comprising: A feedback baseband signal obtained by extracting and demodulating a part thereof, and a distortion amount of the transmission signal are obtained based on a comparison result between the baseband signal and a bias of the amplifier according to the obtained distortion amount. A distortion correction method that changes the voltage. 7. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data, comprising: A feedback baseband signal obtained by extracting and demodulating a part thereof, based on a comparison result of the baseband signal, determines a distortion amount of the transmission signal, and calculates the baseband data according to the determined distortion amount. Distortion correction method for increasing and decreasing the amplitude value of the signal. 8. A distortion correction method for correcting distortion of a transmission signal in a wireless device that amplifies and transmits a modulated signal obtained by modulating a baseband signal based on baseband data, comprising: A feedback baseband signal obtained by extracting and demodulating a part thereof, and a distortion amount of the transmission signal are obtained based on a comparison result between the baseband signal and an output of the amplifier according to the obtained distortion amount. A distortion correction method that increases or decreases part of the feedback gain. 9. The distortion correction method according to claim 6, wherein the baseband signal has been subjected to distortion compensation of a Cartesian feedback system. 10. The distortion correction method according to claim 6, wherein the baseband data has been subjected to an adaptive predistortion type distortion compensation. 11. A wireless device having a distortion correction function, comprising: a power amplifier for amplifying a modulation signal based on baseband data to be transmitted; a unit for extracting a part of an output of the power amplifier; Means for demodulating and converting the baseband data to output as feedback baseband data, and calculating a distortion amount of the output of the power amplifier based on the baseband data to be transmitted and the feedback baseband data. And a bias adjusting unit that changes a bias voltage of the power amplifier based on the calculated distortion amount. 12. A radio apparatus having a distortion correction function, comprising: amplitude changing means for changing the amplitude of baseband data to be transmitted; and a power amplifier for amplifying a modulation signal based on the amplitude-changed baseband data. Means for extracting a part of the output of the power amplifier; means for demodulating the extracted output, converting the output to baseband data, and outputting it as feedback baseband data; and the amplitude-changed baseband data and the feedback. Means for calculating the amount of distortion of the output of the power amplifier based on the baseband data, and the amplitude changing means calculates an amplitude value of the baseband data to be transmitted according to the calculated amount of distortion. A wireless device that increases or decreases. 13. A wireless device having a distortion correction function, comprising: a power amplifier for amplifying a modulation signal based on baseband data to be transmitted; a unit for extracting a part of an output of the power amplifier; Demodulating the baseband data, outputting the feedback baseband data, outputting the feedback baseband data, amplitude control means for controlling the amplitude of the feedback baseband data, the baseband data to be transmitted and the amplitude-controlled feedback Means for calculating the amount of distortion of the output of the power amplifier based on the baseband data, wherein the amplitude control means increases or decreases the amplitude value of the feedback baseband data according to the calculated amount of distortion. Wireless device that is. 14. A radio apparatus having a distortion correction function, comprising: a power amplifier for amplifying a modulation signal based on baseband data to be transmitted; a unit for extracting a part of an output of the power amplifier; A variable gain amplifier that controls the gain of the variable gain amplifier; a unit that demodulates the output of the variable gain amplifier, converts the output to baseband data, and outputs it as feedback baseband data; the baseband data to be transmitted and the feedback baseband data And a means for calculating the amount of distortion of the output of the power amplifier based on the above, wherein the variable gain amplifier increases or decreases the feedback gain in accordance with the calculated amount of distortion. 15. The radio apparatus according to claim 11, further comprising: a distortion compensator of an adaptive predistortion method, wherein the modulated signal is corrected by the distortion compensator. A wireless device obtained based on baseband data. 16. A wireless device having a distortion correction function, comprising: a power amplifier for amplifying a modulated signal obtained by modulating a baseband signal to be transmitted; a unit for extracting a part of an output of the power amplifier; Means for demodulating the output, converting it to a baseband signal, and outputting it as a feedback baseband signal; and calculating the amount of distortion of the output of the power amplifier based on the modulated baseband signal and the feedback baseband signal. And a bias adjusting unit that changes a bias voltage of the power amplifier based on the calculated distortion amount. 17. A wireless device having a distortion correction function, comprising: amplitude changing means for changing the amplitude of baseband data to be transmitted; and means for creating a baseband signal based on the amplitude-changed baseband data. A power amplifier for amplifying a modulated signal obtained by modulating the created baseband signal; a unit for extracting a part of an output of the power amplifier; demodulating the extracted output, converting the output to a baseband signal, and providing a feedback baseband. Means for outputting as a signal; and means for calculating the amount of distortion of the output of the power amplifier based on the modulated baseband signal and the feedback baseband signal. A wireless device for increasing or decreasing the amplitude value of the baseband data to be transmitted according to the amount of distortion. 18. A wireless device having a distortion correction function, comprising: a power amplifier for amplifying a modulation signal based on a baseband signal to be transmitted; a unit for extracting a part of an output of the power amplifier; A variable gain amplifier that controls the gain of the variable gain amplifier; a unit that demodulates an output of the variable gain amplifier, converts the output to a baseband signal, and outputs the baseband signal as a feedback baseband signal; and the modulated baseband signal and the feedback baseband signal. And a means for calculating the amount of distortion of the output of the power amplifier based on the above, wherein the variable gain amplifier increases or decreases the feedback gain in accordance with the calculated amount of distortion. 19. The radio apparatus according to claim 16, further comprising a distortion compensation unit of a Cartesian feedback system, wherein the modulation signal is corrected by the distortion compensation unit. A wireless device obtained based on a baseband signal. 20. The wireless device according to claim 16, further comprising: a distortion compensator of an adaptive predistortion method, wherein the baseband signal to be modulated is provided by the distortion compensator. Wireless device obtained based on the baseband data corrected by.