JP2003087346A - Transmitter for digital wireless device, its automatic phase correction circuit and automatic phase correction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmitter with excellent performance adopting an automatic phase correction circuit and method for coping with a rapid phase change at transmission frequency switching or a phase change due to temperature fluctuations. SOLUTION: The automatic phase correction circuit where part of an output signal extracted from a power amplifier section is fed back via quadrature demodulator (DEMOD) 17 and a phase shifter 20 controls a phase amount of a local carrier in order to compensate nonlinear distortion in the power amplifier section in the case that an amplifier 11 amplifies a transmission signal resulting from the local carrier quadrately modulated by quadrature modulator (MOD) 7 and frequency-modulated with received base band I, Q signals in a transmitter or the like provided with the power amplifier section for amplifying transmission power, includes a phase correction circuit 21 that sets a phase amount of the local carrier through the revision of a transmission frequency from a CPU 22 or the like for controlling the transmitter and corrects the setting phase amount due to a temperature from a temperature sensor 23 in the transmitter.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital radio device including a mobile communication terminal, and more particularly to a transmitter of such a digital radio device and an automatic phase correction circuit and an automatic phase correction suitable for the digital radio device. Regarding the method.

[0002]

2. Description of the Related Art With the rapid progress of communication technology in recent years, particularly in digital mobile communication including mobile communication terminals, for example, a linear modulation method has been widely adopted for power amplification in a transmitting section of a radio device. Therefore, a linear amplifier is required as a power amplifier in the transmitter of mobile communication equipment.

Therefore, such a linear amplifier employs a non-linear distortion compensation technique (linearizer) capable of achieving both the power efficiency of the amplifier and its linearity. One of the representative compensation techniques is as follows. For example, the so-called Cartesian loop method, in which distortion compensation is performed using a signal obtained by demodulating a part of the output of the transmission power amplifier, is already widely known.

By the way, in such a Cartesian loop transmission power amplifier, the stability of the loop is very important because the method is closed loop control. Therefore, phase control of the loop is essential. An example of the transmitter to which the conventional technique is applied is shown in FIG. 7 attached.

Now, the structure of the transmitter having the Cartesian loop type transmission power amplifier according to the above-mentioned prior art will be described. First, baseband I and Q signals are input from the input terminals 1 and 2. These signals are
Band limiting circuits 5 and 6 are added via adders 3 and 4, respectively.
, Where the band is limited so as to obtain a desired loop characteristic, and then input to the quadrature modulator (MOD) 7. The quadrature modulator 7 quadrature-modulates the output from the oscillator 18, which is a local carrier wave, with the input signal to obtain its output, and the output thereof is input to a band pass filter (BPF) 8 in the subsequent stage to remove out-of-band spurious. Will be done. This output is also a mixer
9, the output carrier from the oscillator 19 is mixed and frequency-converted, and the BPF 10
After the out-of-band spurious is removed at, it is input to the power amplifier 11. The power amplifier 11 power-amplifies the input signal, and as a result, the power-amplified output is transmitted from the antenna 13 via the coupler 12.

On the other hand, a part of the output signal of the power amplifier 11 is taken out by the coupler 12 and input to the attenuator 14. The attenuated output is the mixer 15
At, the frequency is converted by mixing with the output carrier of the oscillator 19, and is further input to the quadrature demodulator (DEMOD) 17 via the BPF 16.
The quadrature demodulator 17 quadrature demodulates the input signal into a baseband signal with the output carrier from the oscillator 18, and outputs (I, Q signals) are input to the adders 3 and 4 (closed loop control). . In this figure, reference numeral 25
Is a phase control circuit for automatic phase correction,
Reference numeral 20 is a phase shifter for increasing / decreasing the amount of phase shift by the output from the phase control circuit 25.

Next, the operation of the automatic phase correction system in the transmitter of the prior art whose configuration has been described above will be described below.

In the transmitter automatic phase correction system according to the prior art, the phase control circuit 25, together with the input baseband I and Q signals, receives the quadrature demodulator (DE) as described above.
The quadrature demodulator output baseband I and Q signals demodulated by the MOD) 17 are input. Then, the phase control circuit 25 compares these two input signals, and as a result, when the phase of the quadrature demodulator output baseband signal is delayed with respect to the input baseband I and Q signals, the phase shift circuit 25 shifts the phase. Bowl 20
The automatic phase correction is performed by giving phase correction information that controls the phase shift amount to decrease on the other hand and to increase the phase shift amount when it advances.

The automatic phase correction method of the transmitter as described above is described in, for example, Japanese Patent Registration No. 2746133.

[0010]

[Problems to be Solved by the Invention] As described above,
The automatic phase correction method of the related art is caused by, for example, a rise in temperature around the inside of the housing during transmission operation, that is, a change in the loop phase due to a slow gradual change over a relatively long time. On the other hand, the phase of the output is tracked. Therefore, in the above-mentioned conventional phase correction method, in order to cope with such a slow phase change of the loop, the phase control circuit 25 usually uses its limiter to limit its input signal (input baseband I and Q signals). A phase rotation determination circuit for performing phase comparison after waveform shaping into a rectangular wave, and a determination table that is a table of phase delay / advance determination are configured by a digital circuit. Therefore, a dedicated control digital circuit is required. In addition, there is a problem of spurious deterioration due to leakage of a rectangular wave signal from these digital circuits.

Further, in the above-mentioned conventional technique, the phase control circuit 25 employs a method of following the phase shift amount by the detected phase lead / lag and corresponding counter by up / down. ing. Therefore, for example, when it is used in a usage mode in which the transmission frequency is switched, such as an in-vehicle device, it is not possible to quickly and instantaneously follow a rapid phase change that occurs when the frequency is switched. It was also pointed out that in the worst case, the amplifier might oscillate at the start of the.

In view of the above-mentioned problems and situations in the prior art, the present invention provides a digital radio device capable of handling not only temperature changes but also abrupt phase changes due to changes in transmission frequency. It is an object of the present invention to provide an automatic phase correction circuit and an automatic phase correction method suitable for a transmitter and further for such a digital wireless device.

[0013]

That is, according to the present invention, in order to achieve the above-mentioned object, first, there is provided a transmitter having a power amplification section for amplifying transmission power, wherein the power amplification section comprises: An amplifier is provided for quadrature-modulating the local carrier wave with the input signal to amplify the power of the transmission signal. Further, in order to compensate for the non-linear distortion in the power amplifier, a part of the output signal extracted from the power amplifier is used. A feedback circuit that feeds back through a quadrature demodulator, and a phase shifter that controls the phase of the loop based on the output from the feedback circuit, further comprising the phase shifter based on change information of the transmission frequency. There is provided a transmitter of a digital wireless device, which is provided with a phase correction circuit configured to correct the phase value based on the temperature information from the temperature detecting means together with the means for setting the phase value in the transmitter.

Further, according to the present invention, in the transmitter of the digital radio device described above, the phase value setting means in the phase correction circuit is configured to shift the phase based on the input change information of the transmission frequency. The phase value correction means in the phase correction circuit detects a temperature change based on the temperature information from the temperature detection means, and the detected temperature A temperature change detection circuit that corrects the phase value output from the frequency table based on the change may be provided.

Alternatively, according to the present invention, the phase value setting means in the phase correction circuit calculates a phase value in the phase shifter based on the input change information of the transmission frequency. The phase value correction means in the phase correction circuit,
A temperature change detection circuit may be provided which detects a temperature change based on the temperature information from the temperature detection means and corrects the phase value output from the frequency / phase approximate expression calculation unit based on the detected temperature change. .

According to the present invention, also in order to achieve the above object, in a digital radio device, a non-linear distortion is compensated in a power amplifying unit for quadrature-modulating a local carrier by an input signal and amplifying its power. Therefore, an automatic feedback circuit is provided that includes a feedback circuit that feeds back a part of the output signal extracted from the power amplification unit through a quadrature demodulator, and a phase shifter that controls the phase of the loop based on the output from the feedback circuit. The phase correction circuit further includes means for setting the phase value in the phase shifter based on the change information of the transmission frequency, and means for correcting the phase value based on the temperature information from the temperature detecting means. A phase correction circuit is provided.

According to the present invention, the phase value setting means is based on the input change information of the transmission frequency,
The phase shifter is provided with a frequency table for outputting the phase value, and further, the phase value correcting means detects a temperature change by the temperature information from the temperature detecting means, and detects the detected temperature change. A temperature change detection circuit may be provided for correcting the phase value output from the frequency table based on the temperature change detection circuit.

Alternatively, according to the present invention, in the phase correction circuit described above, the phase value setting means is a frequency for calculating the phase value in the phase shifter based on the input change information of the transmission frequency. Further, the phase value correcting means detects a temperature change based on the temperature information from the temperature detecting means, and based on the detected temperature change, the frequency / phase approximation is performed. A temperature change detection circuit that corrects the phase value output from the expression calculation unit may be provided.

In addition, according to the present invention, in the transmitter of the above-mentioned digital radio or the automatic phase correction circuit, the phase value correction means converts the output signal from the temperature detection means into a digital signal. The temperature information may be obtained by conversion.

Further, according to the present invention, in order to achieve the above-mentioned object, the nonlinear distortion is compensated in the power amplifying unit for quadrature-modulating the local carrier by the input signal and amplifying the power in the digital radio. Therefore, in the automatic phase correction method in which a part of the output signal extracted from the power amplification unit is fed back through the quadrature demodulator, and the phase of the loop is controlled by the phase shifter based on the output from the quadrature demodulator, There is provided an automatic phase correction method of setting the phase value based on the change information of the transmission frequency, detecting a temperature change of the ambient temperature, and correcting the phase value based on the detected temperature change.

As described above, in the present invention, in order to achieve the above object, a frequency table in which a reference temperature is added to a phase correction circuit for responding to a phase change due to a temperature change and a transmission frequency change, or a frequency / phase approximation formula The calculation unit is stored, and only when a temperature change occurs, the reference temperature and the temperature information monitored by the temperature sensor are compared to calculate the temperature difference,
By adding the phase correction value due to temperature change and the optimum phase value at the transmission frequency read from the frequency table, or changing the approximation formula calculated by the frequency / phase approximation formula calculation unit according to the phase correction value due to temperature change. The configuration is such that the optimum phase value of the loop is calculated and given to the phase shifter for automatic phase correction.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings. First, FIG. 1 shows the overall configuration of a transmitter (transmission unit) in a digital wireless device according to an embodiment of the present invention. In this figure, the baseband I and Q signals are input to the input terminals 1 and 2 in the same manner as described in the prior art. In the transmitter, these signals are applied to band limiting circuits 5 and 6 via adders 3 and 4, respectively, where band limiting is performed so as to obtain a desired loop characteristic, and then quadrature modulation is performed. Input to the device (MOD) 7. In addition, this quadrature modulator 7 includes an oscillator 18 which is a carrier wave.
Output (local carrier wave) from the input signal is quadrature-modulated and output, and the output is input to a band pass filter (BPF) 8 in the subsequent stage to remove out-of-band spurious noise. It is the same. Then, this output is mixed with the output carrier from the oscillator 19 in the mixer 9 to be frequency-converted, and further, out-of-band spurious is removed by the BPF 10 and then input to the power amplifier 11. To be done. In addition,
The power amplifier 11 power-amplifies the input signal, and as a result, the power-amplified output is transmitted from the antenna 13 via the coupler 12.

On the other hand, also, a part of the output signal of the power amplifier 11 is extracted by the coupler 12 and input to the attenuator 14. The attenuated output is subjected to frequency conversion by mixing with the output carrier from the oscillator 19 in the mixer 15, and is further passed through the BPF 16 to the orthogonal demodulator (DEMOD).
17 is input. That is, also here, the quadrature demodulator 17 quadrature demodulates the input signal into a baseband signal by the output carrier from the oscillator 18, and inputs its output (I, Q signals) to the adders 3 and 4 described above. (Closed loop control) is the same as the above-mentioned conventional technique.

In the figure, reference numeral 21 indicates a phase control circuit for performing automatic phase correction according to the present invention, and reference numeral 20 indicates an amount of phase shift according to the output from the phase control circuit 21. Is a phase shifter for controlling increase / decrease. Note that the phase control circuit 21 for performing the automatic phase correction according to the present invention, as is clear from the figure, together with the signal (environmental temperature information) detected by the temperature sensor 23 arranged in the transmitter. A control output from a central processing unit (CPU) 22 (for example, a CPU that controls the entire digital wireless device) provided outside the transmitter is input. Further, the temperature sensor 23 is arranged in the housing of the radio device or the transmitter, but it is particularly preferable to be provided in the peripheral portion of a device (for example, a high frequency filter) whose phase changes due to temperature change.

Next, the automatic phase correction method according to the present invention in the transmitter having the configuration described above will be described in detail.

The automatic phase correction method according to the present invention is
In summary, when switching the transmission frequency, the orthogonal demodulator (DEMOD) 17 optimizes the loop phase stored in the phase correction circuit 21 based on the frequency information which is the control information received from the CPU 22. The value of the loop is read and the optimum value is given to the phase shifter 20 to correct the phase of the loop.

The contents of the embodiment relating to the automatic phase correction method according to the present invention will be described in detail below based on two embodiments.

[0028]

First Embodiment First, as a first embodiment of the present invention, an automatic phase correction method using a frequency table will be described in detail below with reference to the attached FIG.

That is, the phase control circuit 21 according to the first embodiment of the present invention, as is apparent from FIG. 2, is an A / D converter for converting the output (temperature information) from the temperature sensor 23 into a digital signal. 24, a frequency table 101 for searching for an optimum phase value corresponding to the control signal (transmission frequency information) from the CPU 22, and the A / D of these.
From a temperature change detection circuit 102 for detecting a temperature change by an output from the converter and the frequency table, and an adder 103 for adding the output from the temperature change detection circuit and the output from the frequency table. It is configured. The output (phase value: Φ (f, t)) from the phase control circuit 21 is input to the phase shifter 20 and the amount of phase shift is controlled based on this, as described above. .

The frequency table 101 here means
As shown in Table 1 below, optimum phase values for a plurality of transmission frequencies are prepared in advance as a table (frequency table), and in Example 1, the values shown in this frequency table are measured. Reference temperature (Tre
f) is also provided as a part of the information (for example,
(Tref = 25 ° C. in this example).

[Table 1]

It should be noted that each transmission frequency (f (MHz)) and phase value (Φ) stored in the frequency table 101.
The relationship with (°)) is proportional (linear) to each other as shown in FIG. 3 attached. Also, FIG.
As shown in, the temperature (T) of the operating environment, which is the ambient temperature, and the above-mentioned phase (Φ) also have a proportional relationship, as in the above.

Next, a first embodiment having the detailed configuration described above.
In the phase control circuit 21 of (1), when the information of the transmission frequency to be changed is output from the CPU 22 that controls the wireless device in response to the change of the receiving area, the information is input to the frequency table 101. . By inputting the change information of the transmission frequency, the frequency table 101 calls the optimum phase value (Φ (F)) of the loop for the change information of the transmission frequency from the phase value stored therein. This phase value is input to the adder 103.

On the other hand, the temperature signal detected by the temperature sensor 23 for detecting the temperature in the wireless device is converted into a digital signal through the A / D converter 24 in the phase control circuit 21, and the temperature information (T ) As temperature change detection circuit 10
Input to 2. At the same time, this temperature change detection circuit 102
Since the reference temperature signal (Tref: here, Tref = 25 ° C.) is input from the frequency table 102, the temperature change (T-Tref) is detected by comparing these two inputs. Then, the temperature change detection circuit 102 detects the detected temperature change (T-T).
ref) based on the temperature correction signal (Δ
Φ (T-Tref)) is output.

At this time, as is apparent from FIGS. 3 and 4, the transmission frequency (f (MHz)) and the phase value (Φ
(°)), the temperature (T), and the phase value (Φ) are in a proportional relationship, respectively, and thus are the optimum phase value of the loop at a predetermined transmission frequency and are detected. The optimal phase value for temperature (T) is corrected by the temperature ((△
[Phi] _T = [Delta] [Phi] (T-Tref)) can be easily obtained by the following formula, for example. _{△ Φ T = △ Φ (T} -Tref) = Φ A + (Φ C -Φ A) × (T-Tref (= 25 ℃)) / 50 Note that, [Phi _A is optimal for a given transmission frequency Of the optimum phase value (Φ) at 0 ° C., and Φ _C is the value of this optimum phase value (Φ) at 50 ° C.

After that, the optimum phase value obtained as described above is corrected by temperature (ΔΦ _T = ΔΦ (T-Tref)).
Is input to the other input terminal of the adder 103 whose optimum phase value (Φ (f)) already searched for in the frequency table 101 is input to one input terminal and added there,
The added output is supplied to the phase shifter 20 as an optimum phase value (Φ
(F, T)).

That is, as apparent from the above description, according to the phase control circuit 21 of the first embodiment, the fact that the temperature (T) and the phase value (Φ) are in a proportional relationship is utilized, that is, , Temperature information (T) from the temperature sensor 23 is input and compared with a reference temperature (for example, Tref = 25 ° C.) provided in the frequency table 102 to obtain a temperature change (T-Tref), and change of the phase value based on the obtained temperature change (T-Tref) (△ Φ T
= [Delta] [Phi] (T-Tref)) is obtained and the correction is performed accordingly.

Next, in the transmitter provided with the phase control circuit 21 whose details have been described above, according to the automatic phase correction method of the present invention, that is, as shown in FIG. Specifically, for example, the temperature sensor 23 installed around the high-frequency filter constantly monitors the temperature that causes a change in the optimum phase value of the loop, and corrects the phase delay / lead thereof. During the transmission operation of the machine, the output phase should always be optimally tracked even if the loop phase fluctuates due to a gradual change over time due to a rise in temperature inside the case. Is possible.

On the other hand, the phase control circuit 21 controls the CPU 2 for controlling the transmitter in accordance with the change of the receiving area.
Since the frequency table 101 is provided for searching and outputting the optimum phase value corresponding to it by the change output of the transmission frequency from 2, the quick and instantaneous follow up to such abrupt phase change. Is possible
As a result, the possibility that the amplifier oscillates as in the conventional case is released.

In addition to the temperature sensor 23 provided in the transmitter, the phase control circuit 21 includes the A / D converter 24, the frequency table 101, the temperature change detection circuit 102, and the addition as described above. It is configured using circuit components that are generally widely used, such as the container 103.
That is, the phase control circuit 21 does not require a dedicated control digital circuit as in the above-described conventional technique, and is free from the problem of spurious deterioration due to leakage of a rectangular wave signal from these digital circuits. . As described above, it is possible to obtain a phase correction method capable of handling not only a gradual phase change due to a temperature change but also a sudden phase change due to a transmission frequency change.

[0040]

Second Embodiment Next, as a second embodiment of the present invention, an automatic phase correction method using a frequency / phase approximate expression calculation unit will be described in detail with reference to the attached FIG. Note that, first, the frequency / phase approximate expression calculation unit 104 used in the second embodiment refers to a certain N (for example, three) transmission frequencies as shown in FIG. (F _L , f _C ,
f _U ), the optimum phase value (Φ ₁ , Φ ₂ , Φ ₃ ) for f _U ), and the function of calculating the optimum phase value for an arbitrary transmission frequency by an approximate expression, and further, temperature information at that time (above). It is the temperature when the relationship between the transmission frequency and the phase value shown in FIG. 3 is established, and is provided with, for example, Tref = 25 ° C.).

The phase control circuit 2 shown in the second embodiment
As is clear from the figure, 1'is also the output (T) of this A / D converter together with the A / D converter 24 which converts the output (temperature information) from the temperature sensor 23 into a digital signal. And a temperature change detection circuit 102 that detects a temperature change based on the temperature information (Tref) from the frequency / phase approximation formula calculation unit 104, and the frequency / phase approximation formula calculation unit 104 described above. Further, the output from the temperature change detection circuit 102 (ΔΦ (T-Tref))
Is input to the frequency / phase approximation formula calculation unit 104 and output from the frequency / phase approximation formula calculation unit 104 (that is, the optimum phase value corrected by the transmission frequency and the temperature change: Φ (f, T )) Is input to the phase shifter 20.

Next, in the phase control circuit 21 'according to the second embodiment described above, for example, the information of the transmission frequency changed by the CPU 22 which controls the radio device is output in accordance with the change of the receiving area. Then, the information is input to the frequency / phase approximate expression calculation unit 104. As a result, the frequency / phase approximate expression calculation unit 104 calculates a phase value for which the phase of the loop is optimum for the changed transmission frequency from the approximate expression, and outputs the calculated phase value, It is an input to the phase shifter 20.

On the other hand, the temperature signal detected by the temperature sensor 23 for detecting the temperature inside the wireless device is also the same as in the above-described first embodiment, that is, the A / D converter 24.
Is converted into a digital signal via and is input to the temperature change detection circuit 102 as temperature information (T). At this time, since the temperature (T) and the phase (Φ) have a proportional relationship as shown in FIG.
By inputting the temperature information (T) and comparing the temperature information (T) with the reference temperature (Tref = 25 ° C.) included in the frequency / phase approximate expression calculating unit 104,
The temperature change (T-Tref) is detected, and accordingly, the phase change amount (ΔΦ) due to the temperature change is corrected. That is,
The temperature correction signal (ΔΦ (T-Tref))
It is output to the phase approximate expression calculation unit 104. So frequency /
The phase approximate expression calculation unit 104 determines whether the temperature correction signal (ΔΦ
(T-Tref)) corrects the phase value calculated by the approximation formula so that the phase of the loop becomes optimum with respect to the change of the transmission frequency, and thus the optimum phase corrected by the change of the transmission frequency and temperature. The value Φ (f, T) will be output to the phase shifter 20.

As described above, also in the second embodiment, as in the case of the first embodiment, the temperature sensor 23 installed in the peripheral portion of the device constantly monitors the temperature sensor 2.
The read value of 3 is input to the A / D converter 24.
The A / D converter 24 digitally converts the read value and uses the output as temperature information (T), which is input to the temperature change detection circuit 102.

On the other hand, the temperature change detection circuit 102 is
The input temperature information (T) is compared with the reference temperature Tref provided in the frequency / phase approximate expression calculation unit 104 in advance to determine whether or not a temperature difference has occurred. Then, when a temperature difference occurs between them, the temperature change detection circuit 102 corrects the so-called phase correction value, which is a correction amount for setting the phase of the loop to the optimum phase value despite the temperature difference. (ΔΦ (T-Tref)) is calculated and output to the frequency / phase approximate expression calculation unit 104.

The phase correction value (ΔΦ (T-Tre
f)) is calculated, for example, when the read value (T) by the temperature sensor is larger than the reference temperature (for example, Tref = 25 ° C.) included in the frequency / phase approximate expression calculation unit 104, the transmission frequency In the phase shifter 20, the phase shift amount is decreased by the optimum phase value (Φ (f)) calculated based on the change, and conversely, when it is small, the phase shift amount is increased. Control the phase correction value of. In addition,
To calculate this phase correction value (ΔΦ (T-Tref)),
For example, the approximation formula shown in the first embodiment can be used.

In this way, the frequency / phase approximate expression calculating unit 104, for example, as shown in the attached FIG. 8, receives the phase correction value (Δ) input from the temperature change detecting circuit 102.
Based on Φ (T-Tref)), the approximate value (Φ (f)) calculated in advance by the frequency / phase approximate expression calculation unit 104 for the change of the transmission frequency is changed, and the change of the transmission frequency and the temperature is performed. The corrected optimum phase value Φ (f, T) is output to the phase shifter 20.

As described above, in the transmitter having the automatic phase correction method of the transmitter of the present invention, the frequency table storing the optimum phase value corresponding to each transmission frequency or the frequency / phase approximate expression calculating unit is used as a reference. Equipped with temperature eliminates the cause of spurious deterioration by eliminating the need for a dedicated control circuit to respond to phase changes due to temperature changes.Furthermore, with the temperature change detection circuit and temperature sensor, the above frequency table or the above approximate expression calculation By comparing the reference temperature provided in the unit and the read value by the temperature sensor, the stability of the loop is always maintained even with a temperature change, and the oscillation of the transmitter is prevented.

[0049]

As is apparent from the above detailed description, according to the transmitter of the digital radio device of the present invention, and further, the automatic phase correction circuit and the automatic phase correction method suitable for the digital radio device. By eliminating the cause of spurious deterioration and optimally responding to not only changes in ambient temperature but also sudden changes in phase due to changes in the transmission frequency, digital radios with stable and excellent characteristics can be obtained. Can be provided.

Further, according to the transmitter of the digital radio and the automatic phase correction circuit suitable for the digital radio, it is possible to provide a digital radio that does not require a dedicated control circuit because of its configuration. Can be done.

[Brief description of drawings]

FIG. 1 is a circuit block diagram showing an overall configuration of a transmitter (transmission unit) in a digital wireless device according to an embodiment of the present invention.

FIG. 2 is a circuit block diagram showing one embodiment (embodiment 1) of the phase correction circuit in the transmitter of the digital wireless device of the present invention.

FIG. 3 is a diagram showing transmission frequency-phase value characteristics of the frequency table shown in FIG.

FIG. 4 is a diagram illustrating a method of calculating a temperature correction value in the phase correction circuit of the first embodiment shown in FIG.

FIG. 5 is a circuit block diagram showing a second embodiment (embodiment 2) of the phase correction circuit in the transmitter of the digital wireless device of the present invention.

FIG. 6 is a diagram illustrating a method of calculating a temperature / phase correction value in the phase correction circuit according to the second exemplary embodiment shown in FIG.

FIG. 7 is a circuit block diagram showing a configuration example of a wireless unit in a conventional digital wireless device.

[Explanation of symbols]

1,2 input terminals 3,4 adder 5,6 Band limiting circuit 7 Quadrature modulator 8,10,16 BPF 9,15 Mixer 11 power amplifier 12 coupler 13 antennas 14 attenuator 17 Quadrature demodulator 18, 19 oscillator 20 Phase shifter 21 Phase correction circuit 22 CPU 23 Temperature sensor 24 A / D converter 25 Phase control circuit 101 frequency table 102 Temperature change detection circuit 103 adder 104 Frequency / Phase Approximation Formula Calculation Unit

Claims (12)

[Claims] 1. A transmitter comprising a power amplification unit for amplifying transmission power, wherein the power amplification unit comprises an amplification unit for orthogonally modulating a local carrier wave by an input signal to amplify the power of the transmission signal. Further, in order to compensate for the non-linear distortion in the power amplification unit, a feedback circuit that feeds back a part of the output signal extracted from the power amplification unit through a quadrature demodulator, and a loop based on the output from the feedback circuit. And a means for setting the phase value in the phase shifter based on the change information of the transmission frequency, the temperature information from the temperature detection means, the phase A transmitter of a digital radio device, comprising a phase correction circuit including means for correcting a value. 2. The transmitter of the digital radio device according to claim 1, wherein the phase value setting means in the phase correction circuit is based on input change information of the transmission frequency, and the phase in the phase shifter is changed. A transmitter of a digital radio, comprising a frequency table for outputting a value. 3. The transmitter of the digital radio device according to claim 2, wherein the phase value correction means in the phase correction circuit detects a temperature change based on temperature information from the temperature detection means, and detects the temperature change. Based on temperature change,
A transmitter of a digital wireless device, comprising a temperature change detection circuit for correcting the phase value output from the frequency table. 4. The transmitter of the digital wireless device according to claim 1, wherein the phase value setting means in the phase correction circuit is based on input change information of the transmission frequency, and the phase in the phase shifter is changed. Frequency to calculate the value /
A transmitter of a digital wireless device, comprising a phase approximation formula calculation unit. 5. The transmitter of the digital wireless device according to claim 4, wherein the phase value correction means in the phase correction circuit detects a temperature change based on temperature information from the temperature detection means, and detects the temperature change. Based on temperature change,
A transmitter of a digital wireless device, comprising a temperature change detection circuit for correcting a phase value output from the frequency / phase approximate expression calculation unit. 6. In a digital radio device, in order to compensate for non-linear distortion in a power amplification unit that orthogonally modulates a local carrier wave by an input signal and amplifies its power, a part of the output signal extracted from the power amplification unit is compensated. In an automatic phase correction circuit including a feedback circuit that feeds back through a quadrature demodulator, and a phase shifter that controls the phase of the loop based on the output from the feedback circuit, further based on the change information of the transmission frequency. An automatic phase correction circuit comprising means for setting a phase value in the phase shifter and means for correcting the phase value based on temperature information from a temperature detection means. 7. The automatic phase correction circuit according to claim 6, wherein the phase value setting means outputs a phase value in the phase shifter based on input change information of the transmission frequency. An automatic phase correction circuit having a table. 8. The automatic phase correction circuit according to claim 7, wherein the phase value correction means detects a temperature change based on temperature information from the temperature detection means, and based on the detected temperature change, the phase value correction means detects the temperature change. An automatic phase correction circuit comprising a temperature change detection circuit that corrects a phase value output from a frequency table. 9. The automatic phase correction circuit according to claim 6, wherein the phase value setting means calculates a phase value in the phase shifter based on input change information of the transmission frequency. An automatic phase correction circuit comprising an approximate expression calculation unit. 10. The automatic phase correction circuit according to claim 9, wherein the phase value correction means detects a temperature change based on temperature information from the temperature detection means, and based on the detected temperature change, the phase value correction means detects the temperature change. An automatic phase correction circuit comprising a temperature change detection circuit for correcting the phase value output from the frequency / phase approximate expression calculation unit. 11. In the transmitter of a digital radio device or the automatic phase correction circuit according to any one of claims 1 to 10, the phase value correction means uses a digital signal as an output signal from the temperature detection means. To obtain the temperature information by converting to a transmitter of a digital wireless device, or
Automatic phase correction circuit. 12. In a digital radio device, in order to compensate for non-linear distortion in a power amplification unit that orthogonally modulates a local carrier wave by an input signal and amplifies its power, a part of the output signal taken out from the power amplification unit is compensated. In the automatic phase correction method of feeding back through the quadrature demodulator and controlling the phase of the loop by the phase shifter based on the output from the quadrature demodulator, the phase value is set based on the change information of the transmission frequency. An automatic phase correction method comprising detecting a change in ambient temperature and correcting the phase value based on the detected change in temperature.