JP2003298358A - Power amplifying device for wireless transmitter, program for controlling power amplifying device, and power amplifying method for wireless transmitter - Google Patents

Abstract

(57) [Problem] To provide a power amplifying device for a wireless transmitter suitable for performing efficient power amplifying. SOLUTION: A power amplification device 4 is provided with a peak value detection unit 4a.
, Absolute value calculation unit 4b, and conversion parameter table 4
c, a multiplier 4d, a QPSK modulator 4e, and a power supply 4
f, and a power amplifying unit 4g, select a conversion parameter corresponding to the absolute value of the peak value calculated from the conversion parameter table 4c, and use the parameter and the multiplier 4d to adjust the signal amplitude. After the conversion, the power supply unit 4f supplies only the power supply voltage of a level appropriate for amplification to the signal amplification unit 4g based on the calculated absolute value of the peak value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power amplifier for a wireless transmitter, and more particularly to a wireless transmitter suitable for enhancing the power amplification efficiency of the power amplifier and especially prolonging the battery life of portable equipment. Power amplifier device for a vehicle.

[0002]

2. Description of the Prior Art Modulation methods used in recent mobile phones and the like are CDMA (Code Division Multiple Access) and O.
FDM (Orthogonal Frequency Division Multiplex)
There are many things that require linearity in the final stage power amplifier circuit as described above. For example, in the W-CDMA system adopted as the standard of the third generation mobile phone system, the wireless transmitter having the configuration shown in FIG. 2 is used.

A conventional radio transmitter will be described below with reference to FIGS. 2 and 3. FIG. 2 shows W-CDMA (Wide band).
It is a figure which shows the structure of the radio transmitter in a Code Division Multiple Access system, FIG.3 (a) is a figure which shows the equivalent circuit of the conventional power amplifier circuit, and FIG.3 (b) is the conventional power amplifier circuit. It is a figure which shows the amplification characteristic of a circuit. As shown in FIG. 2, the wireless transmitter 20 includes a baseband unit 21,
Waveform shaping section 22 and DAC (Digital Analog Converte)
r) 23 and QPSK (Quadrature PhaseShift Keyin
g) converter 24, power amplifier 25, antenna 26
It has a configuration that includes and. Baseband part 21
6 dedicated physical data channels (DPDCH in the figure
(Dedicated Physical Data Channels) and one dedicated physical control channel (DPCCH (Dedicated Phys in the figure)
and the modulated signals input to the respective channels are respectively multiplied by the channelization code Cdi, and then the six DPDCHs are respectively multiplied by the weighting coefficient βd, and the DPCCH is The weighting factor βc is multiplied. Further, each of these channels is I / Q multiplexed and transmitted. Further, the I / Q multiplexed signal is multiplied by a complex scramble code to generate a complex signal s, which is input to the waveform shaping section 22.
Furthermore, the waveform shaping unit 22 shapes the waveform of each of the real part and the imaginary part of the complex signal s, and outputs the signal Re
{S '} and Im {s'} are output, and in the DAC 23, each is converted from a digital signal to an analog signal, and Q
The PSK modulator 24 QPSK-modulates this signal. Then, the modulated signal is transmitted to the final stage power amplification unit 25.
The signal is amplified at and is transmitted from the antenna 26.

Furthermore, the CDMA system solves the near-far problem that strong radio waves arriving from "terminals near the base station" drown out weak radio waves emitted from "terminals away from the base station". Therefore, it is necessary to control the transmission power over a very wide dynamic range. Also, O
In FDM, a large number of orthogonal modulated waves are prepared, and these are analog-multiplexed and transmitted. Therefore, in general, the envelope of the transmission output of W-CDMA or OFDM is not constant but greatly changes due to these factors. For this reason, a highly efficient class C amplifier cannot be used for the final stage power amplifier circuit, and it is necessary to use an amplifier circuit with good linearity.

A conventional power amplifier including a load will be described below with reference to FIG. As shown in FIG.
An equivalent circuit 30 of a conventional power amplification unit including a load has a configuration including a final stage power amplification circuit 31, a load (antenna) 32, and a power supply 33. With such a configuration, the energy supplied from the power supply 33 is finally divided into the load and the power amplification circuit 31, and a part of the energy supplied from the power supply 33 is radiated from the antenna and the rest. Energy will be discarded as heat in the final stage.

[0006]

However, in the equivalent circuit 30 of the power amplifying section including the conventional load described above, when the amplitude of the output voltage is small, the power that is divided by the power amplifying circuit 31 is large and the efficiency is high. Getting worse. Also,
When an attempt is made to increase the amplitude in order to obtain high efficiency, as shown in FIG. 3B, distortion of the signal waveform is generated due to the non-linearity of the power amplification circuit 31 like the amplification result 38 for the input signal 36. If this distortion increases, unnecessary radiation may increase or the error rate of communication information may increase.

Therefore, the present invention has been made by paying attention to the unsolved problem of the conventional technique, and the power amplification for the radio transmitter suitable for efficient power amplification. The purpose is to provide a device.

[0008]

In order to achieve the above object, a power amplifier device for a wireless transmitter according to claim 1 of the present invention is a wireless transmitter for amplifying a signal output from an antenna of the wireless transmitter. A power amplification device for a machine, the signal amplification means for amplifying the signal, and the complementary characteristic for canceling the non-linearity between the input and output of the signal amplification means for the signal before being amplified by the signal amplification means. Signal converting means for converting the signal according to the above-mentioned method, and the signal after being converted by the signal converting means is amplified by the signal amplifying means.

With such a configuration, the signal converting means, with respect to the signal before being amplified by the signal amplifying means,
The conversion processing can be performed according to the inverse characteristic between the input and output of the signal amplifying means, and the signal after the conversion can be amplified by the signal amplifying means. In other words, the amplification characteristic of the signal amplification means has a region that exhibits non-linear amplification characteristics depending on the level of the input signal. Therefore, for an input signal of a voltage level that uses that region for amplification, Output waveform is distorted. Therefore, when such a signal is input, it is necessary to convert the amplitude of the input signal so that it can be absorbed in consideration of the distortion of the waveform, for example, according to the complementary characteristic that cancels the nonlinearity at the time of amplification. Thus, it becomes possible to obtain the desired amplification result.
As a result, the capacity of the non-linear portion in the amplification characteristic of the signal amplifying means is used without waste to perform amplification.
Efficient amplification will be performed.

According to a second aspect of the present invention, in the power amplifier device for a wireless transmitter according to the first aspect, the signal converting means detects a peak value of the signal before the amplification. Means, and signal amplitude converting means for selectively converting the amplitude of the signal before amplification based on the peak value detected by the peak value detecting means.

With such a configuration, the peak value detecting means can detect the peak value of the signal before amplification, and the signal amplitude converting means can detect the signal before amplification based on the detected peak value. It is possible to selectively convert the amplitude of. Therefore, based on the detected peak value, for example, when the voltage level of the signal before amplification is high and the capacity of the nonlinear region in the amplification characteristic of the signal amplification means is used, the distortion of the waveform caused by the amplification is generated. By increasing the amplitude of the signal before amplification so that it can absorb the
It is possible to obtain the desired amplification result and perform the amplification by using the amplification capability of the signal amplification means without waste, and it is possible to perform the efficient amplification. Further, when the peak value is at a level at which amplification can be performed using only the linear region in the amplification capability of the signal amplification means, it is possible not to convert the amplitude of the signal before amplification.

Here, the crest value detecting means is capable of detecting an envelope curve including each crest value of the signal waveform of interest, and the signal amplitude converting means is based on this envelope curve. May be converted. Therefore, for example, it is possible to detect the envelope of the modulated wave and convert the amplitude of the signal input to the amplifier based on this envelope. Compared with the control based on the individual crest value of the signal waveform, the control based on the envelope curve requires a much slower processing speed and is easy to realize.

According to a third aspect of the present invention, in the power amplifying device for a wireless transmitter according to the second aspect, the signal converting means is for converting the amplitude of the signal before being amplified. A conversion parameter table in which parameters are collected, and the signal amplitude conversion means converts the amplitude of the signal before amplification using the conversion parameter based on the detected peak value. Is characterized by.

That is, when converting the amplitude of the signal, the signal converting means prepares a conversion parameter table in which conversion parameters corresponding to the detected peak values are prepared in advance, so that the signal converting means can detect the detected wave. It is possible to read an appropriate conversion parameter from the conversion parameter table according to the high value (for example, the peak value of the modulated wave) and perform amplitude conversion of the signal before amplification based on the parameter.

Therefore, if the amplitude can be converted only by adding or multiplying the conversion parameter to the signal, the amplitude can be converted at a high speed after the peak value is detected. Therefore, the delay due to the amplitude conversion process can be reduced. Here, the conversion parameter is a parameter prepared in advance according to the detected peak value, and is used to correct the amplitude of the signal so that the target amplification result is obtained by using the nonlinear region in the signal amplification means. Is a correction value of. That is, the input signal is converted into an appropriate amplitude by the signal amplitude converting means based on the correction value. For example, by multiplying the conversion parameter and the input signal according to the peak value,
It is conceivable to convert the amplitude of the signal before amplification to an appropriate size.

Further, the crest value detecting means can detect an envelope including each crest value of the target signal waveform, and the signal amplitude converting means determines the conversion parameter based on this envelope. The amplitude of the signal may be converted by utilizing it. Compared with the control based on the individual crest value of the signal waveform, the control based on the envelope curve requires a much slower processing speed and is easy to realize.

A power amplifier for a wireless transmitter according to a fourth aspect of the present invention is a power amplifier for a wireless transmitter that amplifies a signal output from an antenna of the wireless transmitter. A signal amplification means for amplifying the signal, a peak value detection means for detecting a peak value of the signal before being amplified by the signal amplification means, and a signal amplification means based on the peak value detected by the peak value detection means And a supply voltage changing means for changing the level of the power supply voltage.

With such a configuration, the peak value of the signal before amplification can be detected by the peak value detecting means, and the signal amplifying means can be detected by the supply voltage changing means based on the detected peak value. It is possible to change the level of the power supply voltage to be supplied. Therefore, for example, when the detected peak value is a small value, the level of the power supply voltage is changed by the voltage changing means so that the minimum power supply voltage necessary for amplifying the signal is supplied to the signal amplifying means. As a result, it is possible to suppress unnecessary power supply from the power supply when the signal is amplified by the signal amplifying means, and thereby prolong the life of the power supply.

Here, the peak value detecting means can detect an envelope including each peak value of the signal waveform of interest, and the signal amplitude converting means uses the envelope to detect the power supply voltage. You may make it convert a level. Compared with the control based on the individual crest value of the signal waveform, the control based on the envelope curve requires a much slower processing speed and is easy to realize.

A power amplifier for a wireless transmitter according to a fifth aspect of the present invention is a power amplifier for a wireless transmitter for amplifying a signal output from an antenna of the wireless transmitter. A signal amplifying means for amplifying, a peak value detecting means for detecting a peak value of a signal before being amplified by the signal amplifying means, and a signal before the amplification based on the peak value detected by the peak value detecting means. It is characterized by further comprising signal amplitude converting means for selectively converting the amplitude and supply voltage changing means for changing the level of the power supply voltage supplied to the signal amplifying means based on the detected peak value.

With such a configuration, it is possible to detect the peak value of the signal before amplification by the peak value detecting means, and the signal before amplification based on the detected peak value by the signal amplitude converting means. The amplitude of the signal can be converted, and the signal after the conversion of the amplitude can be amplified by the signal amplifying means. It is possible to change the level of the power supply voltage to be supplied.

Therefore, based on the detected peak value, for example, the amplification occurs when the voltage level of the signal before amplification is high and the capacity of the non-linear region in the amplification characteristic of the signal amplification means is used. By increasing the amplitude of the signal before amplification so that the distortion of the waveform can be absorbed,
Amplification can be performed efficiently by using the amplification capability of the signal amplification means, and the amplification can be efficiently performed. Further, when the crest value is at a level at which amplification can be performed using only the linear portion of the amplification capability of the signal amplification means, it is possible not to convert the amplitude of the signal before amplification. Further, based on the detected peak value, for example, by the supply voltage changing means, the power supply voltage is supplied so that only the lowest power supply voltage necessary for obtaining the desired amplification result for the signal is supplied to the signal amplification means. Since it is possible to change the level of the power supply, it is possible to suppress unnecessary power supply from the power supply, and thus it is possible to prolong the life of the power supply. For example, the efficiency of the power supply circuit for changing the power supply voltage to be supplied according to the level of the signal to be amplified can be converted to the target supply voltage with high efficiency by using a voltage changing means such as a DC-DC converter. Partial losses can be minimized.

It should be noted that either the amplitude conversion processing of the signal before amplification by the signal amplitude conversion means or the power supply voltage level change processing by the supply voltage change means is performed based on the detected peak value. Alternatively, both may be combined. In other words, both processes are performed in a combination that maximizes amplification efficiency.

Here, the crest value detecting means can detect an envelope including each crest value of the target signal waveform, and the signal amplitude converting means uses the envelope to detect the amplitude of the signal. And the supply voltage changing means may change the level of the power supply voltage based on the envelope. Compared with the control based on the individual crest value of the signal waveform, the control based on the envelope curve requires a much slower processing speed and is easy to realize.

According to a sixth aspect of the present invention, in the power amplifying device for a wireless transmitter according to the fifth aspect, the signal converting means is for converting the amplitude of the signal before being amplified. A conversion parameter table in which parameters are collected, and the signal amplitude conversion means converts the amplitude of the signal before amplification using the conversion parameter based on the detected peak value. Is characterized by.

That is, when converting the amplitude of the signal, the signal converting means prepares the conversion parameter table in which the conversion parameters corresponding to the detected peak value are prepared in advance. It is possible to read an appropriate conversion parameter from the conversion parameter table according to the high value and perform amplitude conversion of the signal before amplification based on the parameter.

Therefore, if the amplitude conversion can be performed only by adding or multiplying the conversion parameter to the signal, the amplitude conversion can be performed at a high speed after the peak value is detected. Therefore, the delay due to the amplitude conversion process can be reduced. A power amplification device control program according to a seventh aspect of the present invention is a power amplification device control program for controlling the power amplification device for a wireless transmitter according to the first aspect, wherein the signal amplification device is a signal amplification device. Means for converting the signal before being amplified by the means according to a complementary characteristic for canceling the nonlinearity between the input and output of the signal amplifying means, and the signal for amplifying the signal after being converted in the signal converting step. A signal amplification step of amplifying by means.

Here, the present invention is a program for controlling the power amplification device for a wireless transmitter according to claim 1, and description thereof will be omitted because its effects are duplicated. According to an eighth aspect of the invention, in the power amplifier control program according to the seventh aspect, in the signal conversion step, a process of detecting a crest value of the signal before being amplified is performed. It is characterized in that a process for selectively converting the amplitude of the signal before amplification is performed based on the detected peak value.

Here, the present invention is a program for controlling the power amplifying device for a wireless transmitter according to claim 2, and description thereof will be omitted because its effects are duplicated. The invention according to claim 9 is the program for controlling a power amplifier according to claim 8, further comprising a conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected. In the signal amplitude converting step, the amplitude of the signal before amplification is converted based on the detected peak value using the conversion parameter.

Here, the present invention is a program for controlling the power amplification device for a wireless transmitter according to claim 3, and its effects are duplicated, so description thereof will be omitted. A power amplification device control program according to a tenth aspect of the present invention is the power amplification device control program for controlling the power amplification device for a wireless transmitter according to the fourth aspect, wherein the signal is A signal amplifying step for amplifying, a peak value detecting step for detecting a peak value of a signal before being amplified in this signal amplifying step, and supplying to the signal amplifying means based on the peak value detected in the peak value detecting step. And a supply voltage changing step of changing the level of the power supply voltage.

Here, the present invention is a program for controlling the power amplifying device for a wireless transmitter according to claim 4, and description thereof will be omitted because its effects are duplicated. The power amplification device control program according to claim 11 according to the present invention is the power amplification device control program for controlling the power amplification device for a wireless transmitter according to claim 5, wherein the signal is A signal amplification step to amplify, a peak value detection step to detect the peak value of the signal before being amplified in this signal amplification step, and the amplitude of the signal before amplification based on the peak value detected in the peak value detection step A signal amplitude converting step for selectively converting the voltage, a supply voltage changing step for changing the level of a power supply voltage supplied to the signal amplifying means based on the detected peak value,
It is characterized by having.

Here, the present invention is a program for controlling the power amplification device for a wireless transmitter according to claim 5, and description thereof will be omitted because its effects are duplicated. According to a twelfth aspect of the invention, in the power amplifier control program according to the eleventh aspect, in the signal amplitude converting step, the amplitude of the signal before amplification is converted based on the detected peak value. Is provided with a conversion parameter table in which the conversion parameters are collected, and the amplitude of the signal before amplification is converted based on the detected peak value by using the conversion parameter. .

Here, the present invention is a program for controlling the power amplifying device for a wireless transmitter according to claim 6, and description thereof will be omitted because its effects are duplicated. A power amplification method for a wireless transmitter according to claim 13 according to the present invention is a power amplification method for a wireless transmitter that amplifies a signal output from an antenna of the wireless transmitter, and amplifies the signal. A signal before being amplified by the signal amplifying means is converted according to a complementary characteristic for canceling the nonlinearity between the input and output of the signal amplifying means, and the signal after being converted by this processing is converted into the signal amplifying means. It is characterized by performing a process of amplifying with.

That is, the amplification characteristic of the signal amplifying means has a region showing non-linearity depending on the level of the input signal. Therefore, for an input signal of a voltage level which uses that region for amplification, after amplification Output waveform is distorted. Therefore, when such a signal is input, according to the complementary characteristic that cancels the nonlinearity at the time of amplification, for example,
By converting the amplitude of the input signal in consideration of the distortion of the waveform, it is possible to obtain the desired amplification result. As a result, the capacity of the non-linear portion in the amplification characteristic of the signal amplifying means is used without waste, and the amplification is performed efficiently.

The invention according to claim 14 is the invention according to claim 1.
3. The power amplification method for a wireless transmitter according to 3, wherein a process of detecting a peak value of the signal before being amplified is performed, and the amplitude of the signal before amplification is selectively selected based on the peak value detected by this process. Is characterized by performing processing for converting That is, based on the detected peak value, for example,
When the voltage level of the signal before amplification is high and the capacity of the non-linear region in the amplification characteristic of the signal amplification means is used, the distortion of the waveform caused by amplification can be absorbed so that the signal before amplification is By increasing the amplitude, the desired amplification result can be obtained, and the amplification capability of the signal amplification means can be used without waste, and the amplification can be performed efficiently. . Further, when the crest value is at a level at which amplification can be performed using only the linear portion of the amplification capability of the signal amplification means, it is possible not to convert the amplitude of the signal before amplification.

The invention according to claim 15 provides the invention according to claim 1.
4. The power amplification method for a wireless transmitter according to 4, further comprising a conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected, and the conversion is performed based on the detected peak value. It is characterized in that the processing for converting the amplitude of the signal before the amplification is performed using the parameter for use.

That is, if the amplitude can be converted only by adding or multiplying the conversion parameter to the signal, the amplitude can be converted at high speed after the peak value is detected. Therefore, the delay due to the amplitude conversion process can be reduced. A power amplification method for a wireless transmitter according to claim 16 of the present invention is a power amplification method for a wireless transmitter, which amplifies a signal output from an antenna of the wireless transmitter, and amplifies the signal. It is characterized in that processing for detecting the peak value of the signal before being amplified by the signal amplifying means is performed, and processing for changing the level of the power supply voltage supplied to the signal amplifying means based on the peak value detected by this processing is performed. I am trying.

That is, for example, when the detected peak value is a small value, the voltage changing means changes the level of the power supply voltage so that only the power supply voltage necessary for amplifying the signal is supplied to the signal amplifying means. By doing so, it is possible to suppress unnecessary power supply from the power supply when the signal is amplified by the signal amplifying means, and thereby to prolong the life of the power supply.

A power amplification method for a wireless transmitter according to a seventeenth aspect of the present invention is a power amplification method for a wireless transmitter for amplifying a signal output from an antenna of the wireless transmitter. Performing a process of detecting the peak value of the signal before being amplified by the signal amplifying means for amplifying, and performing a process of selectively converting the amplitude of the signal before the amplification based on the peak value detected by this process, It is characterized in that processing for changing the level of the power supply voltage supplied to the signal amplifying means is performed based on the detected peak value.

That is, based on the detected peak value, for example, the amplification occurs when the voltage level of the signal before amplification is high and the capacity of the non-linear region in the amplification characteristic of the signal amplification means is used. By increasing the amplitude of the signal before amplification so that the distortion of the waveform can be absorbed,
The desired amplification result can be obtained, and the amplification can be performed without waste, and the amplification can be efficiently performed. Further, when the crest value is at a level at which amplification can be performed using only the linear portion of the amplification capability of the signal amplification means, it is possible not to convert the amplitude of the signal before amplification. Further, based on the detected peak value, for example, by the supply voltage changing means, the level of the power supply voltage is supplied so that only the power supply voltage necessary for obtaining the target amplification result for the signal is supplied to the signal amplifying means. Can be changed, so that useless power supply from the power supply can be suppressed, and thus the life of the power supply can be extended.

The invention according to claim 18 relates to claim 1.
7. The power amplification method for a wireless transmitter according to 7, further comprising a conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected, and the conversion is performed based on the detected peak value. It is characterized in that the processing for converting the amplitude of the signal before the amplification is performed using the parameter for use.

That is, if the amplitude conversion can be performed only by adding or multiplying the conversion parameter to the signal, the amplitude conversion can be performed at high speed after the peak value is detected. Therefore, the delay due to the amplitude conversion process can be reduced.

[0043]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. 1 to 9 are diagrams showing an embodiment in which the power amplifier device according to the present invention is applied to a W-CDMA wireless transmitter. First, the configuration of the wireless transmitter according to the present invention will be described with reference to FIG. Figure 1
It is a block diagram which shows the structure of the wireless transmitter which concerns on this invention.

The radio transmitter 1 has a structure including a baseband unit 2, a waveform shaping unit 3, a power amplification device 4, and an antenna 5. The baseband unit 2 is similar to the baseband unit 21 in the above-described conventional W-CDMA wireless transmitter 20 and is a known technique, so a detailed description thereof will be omitted.

The waveform shaping section 3 is the conventional W-CD described above.
This is the same as the waveform shaping unit 22 in the MA wireless transmitter 20 and is a known technique, so a detailed description thereof will be omitted. The power amplification device 4 includes a peak value detection unit 4a, an absolute value calculation unit 4b, a conversion parameter table 4c, a multiplier 4d, a QPSK modulation unit 4e, a power supply unit 4f, and a power amplification unit 4g. It has a structure that includes it.

The peak value detecting section 4a detects the peak value of the modulated wave from Re {s '} and Im {s'} which are output signals of the waveform shaping section 3 in FIG. The absolute value calculation unit 4b calculates the absolute value (R
e {s '} ² + Im {s'} ² ) ^1/2 is calculated. The conversion parameter table 4c is used by the absolute value calculation unit 4
Depending on the calculation result of b, the signals Re {s ′} and Im
A conversion parameter for converting the amplitude of {s ′} into a magnitude that cancels the nonlinearity in the amplification characteristic of the power amplification unit 4g is stored, and the conversion parameter according to the acquired absolute value is output. Has become. Here, in the present embodiment, the conversion parameter is a correction for converting the amplitude of the signal before amplification into a size capable of absorbing the attenuation in consideration of the attenuation due to the nonlinear amplification characteristic in the power amplification unit 4g. It is a value.

The multiplier 4d has a conversion parameter and a signal Re output from the conversion parameter table 4c.
{S '} and Im {s'} are respectively multiplied, whereby signals Re {s '} and Im {s'} are multiplied.
Will be converted into a magnitude corresponding to each parameter. The QPSK modulator 4e QPSK-modulates the amplitude-converted signals Re {s '} and Im {s'}, and the QPSK in the conventional radio transmitter 20 described above.
Since the SK modulator 24 is similar to the SK modulator 24 and is a known technique, detailed description thereof will be omitted.

The power supply unit 4f supplies an appropriate power supply voltage, which is not wasted during amplification, to the power amplification unit 4g based on the absolute value calculated by the absolute value calculation unit 4b. It is a power source that can be variably controlled. The power amplification unit 4g uses the supply voltage from the power supply unit 4f to generate QPSK.
It is for amplifying the modulated signal from the modulator 4e.

Further, although not shown, the wireless transmitter 1 is provided with a control unit for controlling the operation of the above-mentioned units and an interface circuit for exchanging data between the above-mentioned units. The above-mentioned control unit generally uses a logic circuit based on hardware in view of the operating speed, but a CPU (Centra)
Program control may be performed by a (Processing Unit). In this case, the ROM that stores the control program
(Read Only Memory) and RAM (Random Access Memo) for temporarily storing data required for program execution
ry), and will be included. In the present embodiment,
A case of controlling using a CPU will be described as an example.

The more specific operation of the wireless transmitter 1 will be described below with reference to FIGS. 8 and 9. FIG. 8A is a diagram showing the amplification characteristic of the signal amplification unit 4g, and FIG. 8B is a diagram showing the complementary characteristic of the amplification characteristic of the signal amplification unit 4g with respect to the non-linear region. (a)-(d) is a figure which shows the signal before amplification and the signal after amplification with and without amplitude conversion.

First, the baseband unit 2 in the radio transmitter 1 has six DPDCHs and one DPCCH, like the above-mentioned baseband unit 21, and these seven channels are I / Q multiplexed. Later, a complex scramble code is multiplied and spread to obtain a complex signal s. Further, this complex signal s is converted into a real part signal Re {s} and an imaginary part signal Im.
After being separated into {s}, the waveforms of these separated signals are shaped by the waveform shaping section 3, and the real part signal R
Obtain e {s '} and imaginary part signal Im {s'}.

These real-part signals Re {s'} after waveform shaping
And the imaginary part signal Im {s ′} are input to the power amplifier 4.
Then, first, in the peak value detecting unit 4a, Re {s'}
And the peak values of Im {s'} are detected, and the detection result is detected.
The result is transmitted to the absolute value calculation unit 4b. In the absolute value calculation unit 4b
Is the absolute value (Re {s'} based on the obtained peak value. ²
+ Im {s'}²)^1/2And convert the calculation result
Transmitted to the parameter table 4c and the power supply unit 4f respectively
To send. The conversion parameter table 4c is the
Based on the logarithmic value, efficient amplification is achieved in the power amplification unit 4g.
Of the signals Re {s '} and Im {s'} as
Conversion parameters for converting the amplitude to an appropriate size
Is output to the multiplier 4d. Where the conversion parameter
The meter table 4c is called a table, but the peak value
Select and output the conversion parameter according to the absolute value of
It has a function to perform processing according to the input absolute value, etc.
ing. The signal amplitude conversion is as shown in FIG.
In addition, the absolute value of the peak value of the signal before amplification is the signal amplification unit 4g.
To use the non-linear region of the amplification characteristic 80 of
In the case of no signal, as shown in FIG.
Complement for converting the non-linear area of the amplification unit 4g into the linear area
In consideration of the characteristic 81, the amplitude of the signal before amplification is set to the nonlinear region.
Convert to a size that can absorb the attenuation at. Tsuma
Normally, as shown in Fig. 9 (a), the signal is increased during amplification.
A signal using the non-linear region of the amplification characteristic of the width part 4g is input.
When applied, as shown in Fig. 9 (b), the wave of the amplified signal
The shape may be distorted and the required amplitude α may not be reached.
is there. Therefore, in the present invention, as shown in FIG.
Consider the complementary characteristic 81 based on the absolute value of the calculated peak value
9 (a) according to the conversion parameters set by
Convert a signal of amplitude x to a signal of amplitude y (increase the amplitude
Signal is modulated by the QPSK modulator 4e, and then the signal is increased.
Input to the width portion 4g. The amplitude-converted signal is shown in FIG.
As shown in (d), distortion occurs after amplification, but the amplitude
The strain is absorbed by the larger
The amplitude α can be obtained.

In the conversion parameter table 4c and the multiplier 4d, the absolute values of the peak values of the signals Re {s '} and Im {s'} are within the range of linearity in the amplification characteristic of the power amplification section 4g. When the level is such that sufficient amplification can be performed, the signals Re {s '} and Im {s'} are QP'd without performing the process of converting the amplitude using the conversion parameter.
It is directly transmitted to the SK modulator 4e.

Further, the signal output from the multiplier 4d is converted into a DAC (Digital Analog Convert) shown in FIG.
er) is converted into an analog signal. This analog signal is modulated by the in-phase carrier and the true-phase carrier in the QPSK modulator 4e and added, and then the power amplifier 4
g. On the other hand, in the power supply unit 4f, when the absolute value of the peak value is acquired from the absolute value calculation unit 4b, the supply voltage level of the power amplification unit 4g is obtained based on the obtained value and the target amplification result is obtained in the power amplification unit 4g. The control is performed by changing the level to a level within a range that is sufficient to be provided and is not wasted.

Then, the power amplification section 4g performs processing for amplifying the input modulated signal with the power supply voltage supplied from the power supply section 4f, and the amplified signal is output from the antenna 5. Become. Next, the flow of the absolute value calculation process of the peak value of the signal before amplification in the power amplification device 4 will be described with reference to FIG. FIG. 4 is a flowchart showing the absolute value calculation processing of the peak value of the signal before amplification in the power amplification device 4.

As shown in FIG. 4, first, step S400.
Then, it is determined whether or not a signal is input from the waveform shaping unit 3. If it is determined that the signal is input (Yes), the process proceeds to step S402, and if not (No), the process waits until it is input. . When the process proceeds to step S402, the peak value detecting unit 4a receives the input signals Re {s'} and Im.
The peak value is detected from {s'}, and the detected peak value is transmitted to the absolute value calculating unit 4b, and the process proceeds to step S404.

In step S404, the absolute value calculation unit 4b
Is the absolute value (Re {s'} based on the obtained peak value.
² + Im {s'} ² ) ^1/2 is calculated and the process proceeds to step S406. After shifting to step S406, the absolute value calculation unit 4b transmits the calculated absolute value to the conversion parameter table 4c and the power supply unit 4f, and shifts to step S400.

That is, the signals are Re {s'} and Im.
Each time {s'} is input, the processing of steps S400 to S406 is performed, the absolute value of the peak value of the signal before amplification is calculated, and the calculation result is converted to the conversion parameter table 4c and the power supply unit 4f. To transmit. Furthermore, the flow of signal amplitude conversion processing in the power amplification device 4 will be described with reference to FIG. FIG. 5 is a flowchart showing a signal amplitude conversion process in the power amplification device 4.

As shown in FIG. 5, first, step S500.
And it is determined whether or not the absolute value of the peak value of the signal is acquired from the absolute value calculation unit 4b, and it is determined that the absolute value is acquired.
(Yes) moves to step S502, otherwise (N
o) waits for acquisition. When the process proceeds to step S502, the conversion parameter table 4c selects the conversion parameter according to the acquired absolute value, transmits it to the multiplier 4d, and proceeds to step S504. If the absolute value is smaller than the predetermined value, the processing of passing the multiplier through may be performed without performing the signal conversion processing. In this case, for example, the power supply unit 4
Only the level of the power supply voltage at f is changed.

In step S504, the acquired conversion parameters and the input signals Re {s'} and Im.
{S '} is multiplied respectively and the multiplication result is QPS
The signal is transmitted to the K modulator 4e and the process proceeds to step S500.
Here, in the present embodiment, as described above, the signal before amplification is subjected to the conversion in which the amplitude is increased so that the desired amplification result is obtained in consideration of the attenuation amount in the power amplification unit 4g. It will be.

That is, every time the absolute value is acquired, step S
The processing from 500 to step S504 is performed, the amplitude of the signal before amplification is converted into an appropriate magnitude, and the converted signal is converted into QPS.
It is transmitted to the K modulator 4e. Further, the flow of the power supply voltage level changing process in the power supply unit 4f will be described with reference to FIG. FIG. 6 is a flowchart showing a power supply voltage level changing process in the power supply unit 4f.

As shown in FIG. 6, first, step S600.
And it is determined whether or not the absolute value of the peak value of the signal is acquired from the absolute value calculation unit 4b, and it is determined that the absolute value is acquired.
(Yes) moves to step S602, otherwise (N
o) waits for acquisition. When the process proceeds to step S602, the power amplification unit 4g is based on the acquired absolute value.
Then, the voltage level is changed so that the power supply voltage level necessary for amplification can be supplied, and the process proceeds to step S604. Here, in the present embodiment, the level of the power supply voltage is based on the absolute value of the peak value, and further, in accordance with the level of the signal converted by the conversion parameter, it is appropriate that there is no unnecessary power consumption during amplification. It is controlled by the level.

When the process proceeds to step S604, the changed power supply voltage is supplied to the power amplifying section 4g and the step S60 is performed.
Move to 0. That is, the processing of steps S600 to S604 is performed every time the absolute value is acquired, and the level of the power supply voltage supplied to the power amplification unit 4g is changed based on the absolute value. Furthermore, the flow of power amplification processing in the power amplification unit 4g will be described with reference to FIG. FIG. 7 shows a power amplification unit 4g.
4 is a flowchart showing a power amplification process in FIG.

As shown in FIG. 7, first, step S700.
If it is determined that the signal is input (Yes), the process proceeds to step S702; otherwise (No), the process waits until it is input. When the process proceeds to step S702, the signal is amplified by the power supply voltage supplied from the power supply unit 4f, and then the process proceeds to step S7.
Move to 04.

When the process proceeds to step S704, the amplified signal is output to the antenna 5 and the process proceeds to step S706. That is, each time a signal is input, step S70
The processing from 0 to step S704 is performed to amplify the input signal. As described above, the power amplification device 4 in the wireless transmitter 1
In step 1, before amplifying the signal, the absolute value of the peak value of the signal is calculated, and based on the calculation result, the target amplification result is obtained in the power amplification unit 4g for the signal larger than the predetermined level. In addition, the amplitude of the signal is converted to a size that can absorb the attenuation at the time of amplification so that amplification is performed using the nonlinear region in the amplification characteristic. The amplification efficiency in the portion 4g is improved.

Further, when converting the amplitude of the signal, a conversion parameter corresponding to the absolute value of the calculated peak value of the signal is prepared in advance as the conversion parameter table 4c, and the high speed is achieved after the calculation of the absolute value. Since the signal amplitude can be converted, the delay caused by the conversion can be reduced. Further, the power supply unit 4f changes the level of the power supply voltage supplied to the power amplification unit 4g based on the calculated absolute value of the peak value of the signal, so that the level of the supplied voltage is appropriate without waste. The power consumption efficiency at the time of amplifying the signal is improved by adopting this method.

Here, the peak value detecting section 4a shown in FIG.
Corresponds to the peak value detecting means according to claims 2, 4, and 5,
The signal amplitude conversion processing performed by the multiplier 4d using the conversion parameter corresponds to the signal amplitude conversion means according to claims 2, 3, 5 and 6, and the power supply voltage level change processing in the power supply unit 4f is Corresponding to the supply voltage changing means according to claim 4 and claim 5, the power amplification unit 4g,
It corresponds to the signal amplifying means described in 4, 5, 7, 13, 16, and 17.

In the above embodiment, an example in which the present invention is applied to a W-CDMA radio transmitter is described, but the present invention is not limited to this, and a radio transmitter of an OFDM system or another modulation system is used. May be applied to. Further, in the above-described embodiment, the power amplification device having both the signal amplitude conversion processing function and the power supply voltage level change processing function is described. You may make it provide only one function.

Further, when only the power supply voltage level changing processing function is provided, the voltage level supplied to the power amplifying section is changed to the same level as the maximum peak value detected by the peak value detecting section. Alternatively, it may be changed based on the detected peak value.

[0070]

As described above, according to the power amplifying device for the wireless transmitter of the first aspect of the present invention, the signal which uses the non-linear region of the amplification characteristic in the signal amplifying means for the amplification is generated. According to the non-linearity complementing characteristics at the time of input, for example, considering the amount of distortion in the waveform and converting the amplitude of the signal before amplification to absorb that amount, the desired amplification result Can be obtained. As a result, since the capacity of the non-linear portion in the amplification characteristic of the signal amplifying means is used without waste, the amplification can be performed efficiently.

Further, according to the power amplifying device for the wireless transmitter of the second aspect, in addition to the effect of the first aspect, based on the detected peak value, for example, the voltage level of the signal before amplification is high. , When the capacity of the non-linear region in the amplification characteristic of the signal amplification means is used, the amplitude of the signal before amplification is increased so that the distortion of the waveform generated by the amplification can be absorbed. It becomes possible to perform amplification without waste of the amplification capacity of the means, and it becomes possible to perform amplification efficiently. Further, when the peak value is at a level at which amplification can be performed using only the linear region in the amplification capability of the signal amplification means, it is possible not to convert the amplitude of the signal before amplification.

Further, according to the power amplification device for the wireless transmitter of the third aspect, when converting the amplitude of the signal, a conversion parameter in which conversion parameters corresponding to the detected peak value are collected in advance. Since the parameter table was prepared, if the amplitude conversion can be performed only by adding or multiplying the conversion parameter to the signal, the amplitude conversion can be performed at high speed after the peak value is detected. Is possible,
It is possible to reduce the delay due to the amplitude conversion process.

According to the power amplifying device for the wireless transmitter of the fourth aspect, when the detected peak value is a small value, only the power supply voltage necessary for amplifying the signal is used as the signal amplifying means. Since the level of the power supply voltage is changed by the voltage changing means so that the power is supplied to the power supply circuit, it is possible to suppress unnecessary power supply from the power supply when the signal is amplified by the signal amplifying means, thereby extending the life of the power supply. It will be possible.

Further, according to the power amplifying device for the wireless transmitter of the fifth aspect, based on the detected peak value, for example, the voltage level of the signal before amplification is high and the amplification characteristic of the signal amplifying means is not high. When the capacity of the linear region is used, the amplitude of the signal before amplification is converted so that the distortion of the waveform generated by amplification can be absorbed, so the amplification capacity of the signal amplification means is not wasted. It becomes possible to carry out amplification by using it, and it becomes possible to carry out amplification efficiently. Furthermore, based on the detected peak value,
For example, the supply voltage changing means changes the level of the power supply voltage so that only the power supply voltage necessary for obtaining the desired amplification result for the signal is supplied to the signal amplifying means. It is possible to suppress the useless power supply of the power source, and thus to prolong the life of the power source. Further, according to the power amplification device for a wireless transmitter of claim 6, when converting the amplitude of a signal, a conversion parameter table in which conversion parameters corresponding to detected peak values are collected in advance is created. Since it was prepared, if the amplitude can be converted only by adding or multiplying the conversion parameter to the signal, it will be possible to perform the amplitude conversion at high speed after detecting the peak value. ,
It is possible to reduce the delay due to the amplitude conversion process.

Here, the power amplifier control program according to any one of claims 7 to 12 is defined by any one of claims 1 to 6.
It is a program for controlling each of the power amplification devices for the wireless transmitters described, and the description thereof is omitted because the effects thereof overlap. Further, regarding the effect of the power amplification method for a wireless transmitter according to any one of claims 13 to 18, claim 1
The power amplification device for a wireless transmitter according to claim 6 realizes the method, and the description thereof is omitted because the effects are duplicated.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a wireless transmitter according to the present invention.

FIG. 2 is a diagram showing a configuration of a wireless transmitter in the W-CDMA system.

FIG. 3A is a diagram showing an equivalent circuit of a conventional power amplification circuit, and FIG. 3B is a diagram showing amplification characteristics of the conventional power amplification circuit.

FIG. 4 is a flowchart showing a process of calculating an absolute value of a peak value of a signal before amplification in the power amplification device 4.

5 is a flowchart showing an amplitude conversion process of a signal before amplification in the power amplification device 4. FIG.

FIG. 6 is a flowchart showing a power supply voltage level changing process in the power supply unit 4f.

FIG. 7 is a flowchart showing a power amplification process in a power amplification unit 4g.

FIG. 8A is a diagram showing an amplification characteristic of the signal amplification unit 4g, and FIG. 8B is a diagram showing a complementary characteristic of the amplification characteristic of the signal amplification unit 4g with respect to a non-linear region.

9A to 9D are diagrams showing a signal before amplification and a signal after amplification with and without amplitude conversion.

[Explanation of symbols]

1 wireless transmitter 2 Baseband section 3 Wave shaping unit 4 Power amplifier 4a Peak value detector 4b Absolute value calculator 4c conversion parameter table 4d multiplier 4e QPSK modulator 4f power supply 4g power amplifier 5 antennas

Continued front page    F term (reference) 5J091 AA01 AA41 CA21 CA36 FA20                       KA00 KA33 KA34 KA53 MA14                       MA20 SA14 TA01 TA06 TA07                 5J092 AA01 AA41 CA21 CA36 FA20                       KA00 KA33 KA34 KA53 MA14                       MA20 SA14 TA01 TA06 TA07                 5J500 AA01 AA41 AC21 AC36 AF20                       AK00 AK33 AK34 AK53 AM14                       AM20 AS14 AT01 AT06 AT07                 5K060 BB07 CC04 DD04 FF06 HH06                       KK02 LL14

Claims (18)

[Claims] 1. A power amplifier for a wireless transmitter for amplifying a signal output from an antenna of a wireless transmitter, the signal amplifying means for amplifying the signal, and a signal before being amplified by the signal amplifying means. And signal conversion means for converting the signal according to a complementary characteristic that cancels out the nonlinearity between the input and output of the signal amplification means, and the signal after being converted by the signal conversion means is amplified by the signal amplification means. A power amplifier device for a wireless transmitter, characterized in that 2. The signal converting means detects a peak value of the signal before being amplified, and a peak value detecting means, and selectively selects the peak value before the amplification based on the peak value detected by the peak value detecting means. 2. A power amplification device for a wireless transmitter according to claim 1, further comprising a signal amplitude conversion means for converting the amplitude of the signal. 3. The signal conversion means includes a conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are converted, and the signal amplitude conversion means includes the detected wave. The power amplification device for a wireless transmitter according to claim 2, wherein the amplitude of the signal before amplification is converted by using the conversion parameter based on a high value. 4. A power amplifier device for a wireless transmitter for amplifying a signal output from an antenna of a wireless transmitter, the signal amplifying means for amplifying the signal, and a signal before being amplified by the amplifying means. A peak value detecting means for detecting a peak value, and a supply voltage changing means for changing a level of a power supply voltage supplied to the signal amplifying means based on the peak value detected by the peak value detecting means. Power amplifier for wireless transmitter. 5. A power amplifier for a wireless transmitter for amplifying a signal output from an antenna of the wireless transmitter, the signal amplifying means for amplifying the signal, and a signal before being amplified by the signal amplifying means. Crest value detecting means for detecting a crest value of, a signal amplitude converting means for selectively converting the amplitude of the signal before amplification based on the crest value detected by the crest value detecting means, and the detected crest value Power supply voltage changing means for changing the level of the power supply voltage supplied to the signal amplifying means based on the above. 6. The signal conversion means comprises a conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected, and the signal amplitude conversion means includes the detected wave. The power amplification device for a wireless transmitter according to claim 5, wherein the amplitude of the signal before amplification is converted by using the conversion parameter based on a high value. 7. A power amplification device control program for controlling the power amplification device for a wireless transmitter according to claim 1, wherein the signal before being amplified by said signal amplification means is said signal amplification means. And a signal amplification step of amplifying the signal after the conversion in the signal conversion step by the signal amplification means. And a program for controlling the power amplifier. 8. In the signal converting step, a process of detecting a peak value of the signal before being amplified is performed, and an amplitude of the signal before being amplified is selectively selected based on a peak value detected by this process. The power amplification device control program according to claim 7, wherein the conversion processing is performed. 9. A conversion parameter table in which conversion parameters for converting the amplitude of the signal before the amplification are converted is provided, and in the signal amplitude conversion step,
9. The power amplification device control program according to claim 8, wherein the amplitude of the signal before amplification is converted by using the conversion parameter based on the detected peak value. 10. A power amplification device control program for controlling the power amplification device for a wireless transmitter according to claim 4, comprising a signal amplification step of amplifying the signal, and an amplification step performed in the signal amplification step. A peak value detecting step of detecting the peak value of the signal before the step, and a supply voltage changing step of changing the level of the power supply voltage supplied to the signal amplifying means based on the peak value detected in the peak value detecting step. A program for controlling a power amplification device, comprising: 11. A power amplification device control program for controlling the power amplification device for a wireless transmitter according to claim 5, comprising a signal amplification step of amplifying the signal, and an amplification step performed in the signal amplification step. Crest value detecting step for detecting the crest value of the signal before amplification, a signal amplitude converting step for selectively converting the amplitude of the signal before amplification based on the crest value detected in the crest value detecting step, and the detection A power supply voltage changing step of changing the level of the power supply voltage supplied to the signal amplifying means based on the peak value thus obtained. 12. The signal amplitude converting step includes a conversion parameter table that collects conversion parameters for converting the amplitude of the signal before amplification based on the detected peak value, and the detected parameter is detected. The power amplification device control program according to claim 11, wherein the amplitude of the signal before the amplification is converted using the conversion parameter based on a peak value. 13. A power amplification method for a wireless transmitter for amplifying a signal output from an antenna of a wireless transmitter, wherein the signal before being amplified by a signal amplification means for amplifying the signal is the signal amplification means. For a wireless transmitter characterized by performing a process of converting according to a complementary characteristic that cancels out the non-linearity between the input and output, and performing a process of amplifying the signal converted by this process by the signal amplifying means. Power amplification method. 14. A process of detecting the peak value of the signal before being amplified, and a process of selectively converting the amplitude of the signal before being amplified based on the peak value detected by this process. 14. A power amplification method for a wireless transmitter according to claim 13, characterized in that 15. A conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected, and the amplification is performed by using the conversion parameter based on the detected peak value. The power amplification method for a wireless transmitter according to claim 14, further comprising a step of converting the amplitude of the previous signal. 16. A power amplification method for a wireless transmitter for amplifying a signal output from an antenna of the wireless transmitter, wherein a crest value of a signal before being amplified by a signal amplification means for amplifying the signal is detected. A power amplification method for a wireless transmitter, characterized in that processing is performed, and processing for changing the level of the power supply voltage supplied to the signal amplification means is performed based on the peak value detected by this processing. 17. A power amplification method for a wireless transmitter for amplifying a signal output from an antenna of a wireless transmitter, wherein a crest value of a signal before being amplified by a signal amplification means for amplifying the signal is detected. Processing, and processing for selectively converting the amplitude of the signal before amplification based on the peak value detected by this processing, and the level of the power supply voltage supplied to the signal amplifying means based on the detected peak value. A power amplification method for a wireless transmitter, characterized in that the power amplification method is performed. 18. A conversion parameter table in which conversion parameters for converting the amplitude of the signal before being amplified are collected, and the amplification is performed by using the conversion parameter based on the detected peak value. 18. The power amplification method for a wireless transmitter according to claim 17, further comprising the step of converting the amplitude of the previous signal.