JP2004080290A - Communication apparatus with function for compensating offset of transmission power detection circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication apparatus with a function for compensating an offset of a transmission power detection circuit that compensates offset variations in an input voltage to an analog/digital converter and fully utilizes a dynamic range of the analog/digital converter so as to enhance the accuracy of analog/digital conversion and improve the accuracy of transmission power control. <P>SOLUTION: A first detection diode D1 detects a transmission signal extracted form a directional coupler CPU of a transmission system circuit section and an adder circuit 7-2 receives the detected signal via a high frequency elimination filter LPF. The adder circuit 7-2 receives an output voltage of a second detection diode D2 compensating a characteristic change in the first detection diode D1 due to temperature via a reference circuit 7-1 and compensates the temperature by adding a temperature compensation signal to the transmission power detection signal from the first detection diode D1. An offset code is given to an electronic volume 1-1 for adjusting the bias voltage of the adder circuit 7-2 and the electronic volume 1-1 adjusts an input voltage of the analog/digital converter 7-3 to be a voltage not causing an offset from an original reference value. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a communication device having an offset compensation function of a transmission power detection circuit. 2. Description of the Related Art In a W-CDMA (Wide band Code Division Multiple Access) communication system, a code spread transmission method in which the same frequency is shared by many user communication devices is adopted.
[0002]
In such a communication system, in order to prevent interference between communication signals of the same frequency, each communication device transmits with a minimum necessary transmission power, and a regulation regarding an upper limit of transmission power is set so as to minimize unnecessary transmission power. Strictly defined. The present invention relates to a communication device having an offset compensation function of a transmission power detection circuit for performing transmission power control.
[0003]
[Prior art]
FIG. 6 shows functional blocks of a mobile wireless communication device that performs transmission power control. In the figure, 6-1 is an antenna, 6-2 is an antenna duplexer, 6-3 is a reception system circuit unit, 6-4 is a local system circuit unit, 6-5 is a transmission system circuit unit, and 6-6 is detection. A circuit, 6-7 is a baseband processing unit, and 6-8 is a control unit.
[0004]
The signal received from the antenna 6-1 is input to the reception system circuit unit 6-3 via the antenna duplexer 6-2, and the reception system circuit unit 6-3 transmits the signal from the local system circuit unit 6-4. The number of frequencies is converted into a baseband signal using the transmission frequency signal, and the baseband processing unit 6-7 performs signal demodulation processing.
[0005]
On the other hand, the transmission signal output from the baseband processing unit 6-7 is frequency-converted into a radio frequency signal in the transmission system circuit unit 6-5 using the local oscillation frequency signal from the local system circuit unit 6-4. It is transmitted from the antenna 6-1 via the duplexer 6-2.
[0006]
A part of the transmission signal output from the transmission system circuit unit 6-5 is input to the detection circuit 6-6, and the detection circuit 6-6 monitors the transmission power so that unnecessary transmission power is not output. An APC (Automatic Power Control; automatic transmission power control) is performed on the transmission signal power output from the baseband processing unit 6-7.
[0007]
In order to realize the APC (automatic transmission power control) function, transmission signal power detection plays an important role, and a diode detection circuit is mainly used as the detection circuit. FIG. 7 shows a configuration of a conventional transmission power detection circuit. In FIG. 7, PA, CUP, and ISO indicate a transmission power amplifier, a directional coupler, and an isolator in the transmission system circuit unit 6-5, respectively. DUP and SW indicate a frequency sharing filter and an antenna switching device in the antenna sharing device 6-2, respectively.
[0008]
A part of the transmission signal transmitted from the transmission power amplifier PA of the transmission system circuit unit and transmitted from the antenna is distributed to a detection circuit from the directional coupler CPU connected to the output terminal of the transmission power amplifier PA. The output signal from the directional coupler CPU is detected by the capacitor C1 and the first detection diode D1, converted into a voltage, and input to the addition circuit 7-2 via the high frequency removal filter LPF. The first and second resistors R1 and R2 are resistors for setting a bias voltage.
[0009]
Since the characteristics of the first detection diode D1 change with temperature, in order to perform temperature compensation, a second detection diode D2 having the same temperature characteristics as the first detection diode D1 is connected to the first detection diode D1. Connected to the same bias voltage setting resistors R1 ′ and R2 ′ as the set bias voltage setting resistors, and outputs the output voltage of the second diode D2 via the reference value circuit 7-1. Input to -2.
[0010]
The reference value circuit 7-1 includes an input resistor R3, a feedback resistor R4, and a first operational amplifier OP1, and inverts and amplifies the temperature compensation signal voltage level output from the second detection diode D2. The polarity inversion signal of the temperature compensation signal is added to the addition circuit 7-2.
[0011]
The adder circuit 7-2 includes first and second input resistors R5 and R5 ', a feedback resistor R6, and a second operational amplifier OP2, and is obtained from the first detection diode D1 via a high-frequency elimination filter LPF. The transmission power detection signal and the polarity inversion signal of the temperature compensation signal obtained from the second detection diode D1 via the reference value circuit 7-1 are transmitted via the first and second input resistors R5 and R5 ', respectively. By inputting and adding them, the characteristic change due to the temperature of the first detection diode D1 is canceled out and compensated.
[0012]
Power detection that performs temperature compensation using the first and second detection diodes D1 and D2 is also referred to as “rectified dual diode detection”. The transmission power detection signal output from the addition circuit 7-2 is converted from an analog signal into a digital code (for example, an 8-bit digital signal) by the A / D converter 7-3.
[0013]
[Problems to be solved by the invention]
The conventional transmission power detection circuit shown in FIG. 7 can compensate for the temperature characteristics of the detection diode, but it does not provide the variation in the reference voltages REF1 and REF2 of the first and second operational amplifiers OP1 and OP2 and the A / D converter. With the accuracy of 7-3, the input voltage of the A / D converter 7-3 with respect to the detected transmission power becomes a voltage shifted from the original reference value as shown in FIG.
[0014]
8, the horizontal axis indicates the detected transmission power [dBm], the vertical axis indicates the input voltage of the A / D converter 7-3, the solid line indicates the original reference value of the A / D converter input voltage, and the broken line indicates the above. 3 shows the deviation (offset) of the input voltage of the A / D converter caused by the variation of the A / D converter.
[0015]
Since a deviation (offset) of the A / D converter input voltage occurs, a voltage range including an offset variation becomes the input voltage of the A / D converter as a dynamic range of the A / D converter input voltage. In addition, the voltage output characteristics of the transmission power detection were adjusted. For this reason, the accuracy per bit of the A / D converter becomes coarse, and this causes the accuracy of APC (automatic transmission power control) of transmission power to deteriorate.
[0016]
The present invention compensates for and removes the offset fluctuation of the input voltage of the A / D converter, and makes full use of the dynamic range of the input voltage of the A / D converter to make one bit (one code) of the A / D converter. ), And to improve the accuracy of APC (automatic transmission power control) of transmission power.
[0017]
[Means for Solving the Problems]
A communication device having an offset compensation function of a transmission power detection circuit according to the present invention includes: (1) a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of the transmission power detection circuit from an analog signal to a digital signal; Analog voltage control for converting an output voltage of the transmission power detection circuit from a reference value, the offset error being read from a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal, to an analog voltage And a means for feeding back an output voltage of the analog voltage control circuit to a reference voltage of an operational amplifier in the transmission power detection circuit to compensate for the offset error.
[0018]
(2) In a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of a transmission power detection circuit from an analog signal to a digital signal, an offset error of the output voltage of the transmission power detection circuit with respect to a reference value An offset voltage read from a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal, an analog voltage control circuit that converts the error into an analog voltage, the output voltage of the analog voltage control circuit, A means for compensating the offset error by feeding back to a reference voltage of an A / D converter for converting an analog signal to a digital signal.
[0019]
Further, (3) a memory storing the offset error value observed in advance, and a means for providing the offset error value stored in the memory to the analog voltage control circuit together with an initial setting value when power is turned on.
[0020]
(4) The transmission power in the transmission of the control information immediately before the start of the user data transmission is detected by the transmission power detection circuit, and an offset error read from a digital code obtained by converting the detected analog voltage into a digital signal is calculated as the offset error. It is provided with means for giving to the voltage control circuit.
[0021]
And (5) means for providing the analog voltage control circuit with a different offset error value for each frequency band of the transmission signal based on a digital code obtained by converting the output voltage of the transmission power detection circuit from an analog signal to a digital signal. It is a thing.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows a configuration example of a transmission power detection circuit according to the present invention. In the figure, a transmission power amplifier PA, a directional coupler CUP, an isolator ISO, a frequency sharing filter DUP, and an antenna switch SW are the same as those in the conventional transmission power detection circuit shown in FIG.
[0023]
The transmission signal extracted from the directional coupler CPU of the transmission circuit section is detected by the capacitor C1 and the first detection diode D1, and passed through the high-frequency elimination filter LPF, similarly to the conventional transmission power detection circuit of FIG. Is input to the addition circuit 7-2.
[0024]
Further, a second detection diode D2 for compensating for a characteristic change due to temperature of the first detection diode D1 is replaced with a bias voltage setting resistor R1 similar to the bias voltage setting resistors R1 and R2 of the first detection diode D1. , R2 ', and the output voltage of the second diode D2 is input to the addition circuit 7-2 via the reference value circuit 7-1. The reference value circuit 7-1 inverts the polarity of the signal level for temperature compensation output from the second detection diode D2 and amplifies the same, as in the transmission power detection circuit of FIG. 7, and inverts the polarity of the temperature compensation signal. The signal is applied to the addition circuit 7-2.
[0025]
The adder circuit 7-2 includes first and second input resistors R5 and R5 ', a feedback resistor R6, and a second operational amplifier OP2, similarly to the transmission power detection circuit of FIG. A transmission power detection signal obtained from D1 via a high-frequency elimination filter LPF and a polarity inversion signal of a temperature compensation signal obtained from a second detection diode D2 via a reference value circuit 7-1 are first and second signals. The input voltage is input through the second input resistors R5 and R5 ', and these are added to compensate for the characteristic change of the first detection diode D1 due to temperature.
[0026]
The transmission power detection circuit according to the present invention includes an analog voltage control circuit (for adjusting the bias voltage of the addition circuit 7-2 according to the offset error of the voltage conversion characteristic of the transmission power detection signal obtained by the rectified dual diode detection). An electronic volume) 1-1 is provided, and an offset code is given to the analog voltage control circuit (electronic volume) 1-1 so that the input voltage of the A / D converter 7-3 shifts (offset) from the original reference value. Adjust so that the voltage does not occur.
[0027]
As a result, the dynamic range of the input voltage of the A / D converter 7-3 can always be kept at a constant value, and the dynamic range of the input voltage of the A / D converter 7-3 can be used effectively to the maximum. The accuracy per bit of the A / D converter 7-3 is improved, and the accuracy of APC (automatic transmission power control) can be improved.
[0028]
The transmission power detection signal output from the addition circuit 7-2 is converted from an analog signal into a digital signal (for example, an 8-bit digital code) by an A / D converter 7-3, and is converted into an APC (automatic transmission power control) signal. (APC code) is input to the control unit 6-8. The control unit 6-8 performs a calculation process for correcting the transmission power based on the APC code. In addition, in the correction based on the analog voltage, a correction error is further generated, so that the correction by digital processing is the most efficient method.
[0029]
The A / D converter 7-3 stores in advance a table of A / D converter output codes (APC codes) for transmission power (hereinafter, referred to as “APC table”). The APC table includes a plurality of tables according to the frequency band of the transmission signal because the detection signal of the transmission power varies depending on the frequency of the transmission signal and the like.
[0030]
FIG. 2 shows a configuration example including three APC tables. As shown in the figure, an analog voltage signal whose transmission power has been detected is converted into a digital code by an A / D converter 2-1, and the digital code is converted into three APC tables 2-21, 22-2, and 2-23. To enter.
[0031]
One of the three APC tables 2-21, 22-2, and 2-23 is selected by the changeover switch (SW) 2-3 according to the frequency band of the transmission signal, and is converted into an APC code corresponding to the transmission power. Then, the APC code is output to the control unit 6-8. As described above, the accuracy of APC (automatic transmission power control) is maintained by converting the digital code output from the A / D converter into an APC code by switching between different APC tables for each frequency.
[0032]
As a variation of the transmission power detection signal due to the frequency, a detection circuit cannot distinguish a signal generated at the input end of the transmission power amplifier (PA) from a signal generated inside the transmission power amplifier (PA). Therefore, there is no other choice but to perform correction after detecting the output signal of the transmission power amplifier (PA).
[0033]
Therefore, based on the digital code obtained by A / D conversion of the transmission power detection signal, a different offset error value for each frequency band of the transmission signal is given to the above-described analog voltage control circuit (electronic volume) 1-1 to reduce the offset error. By removing the APC table, transmission power control can be performed using one APC table without providing a plurality of APC tables, and the memory can be significantly reduced.
[0034]
The transmission power detection circuit based on dual diode detection can cancel the temperature fluctuation of the detection diode D1, and can replace the faithful detection voltage of the transmission power with a digital code by the A / D converter 7-3. In the reference value circuit 7-1 for canceling the temperature fluctuation, the gain G of the amplifier including the operational amplifier OP1 for amplifying the output voltage of the diode D2 to be replaced with the reference value is set to 1. However, the embodiment is not limited to this.
[0035]
The adder circuit 7-2 is configured using an analog adder circuit including an operational amplifier OP2 to add the reference value and cancel the detection error of the diode D1, and to adjust the dynamics of the input voltage of the A / D converter 7-3. The gain G of the analog addition circuit was set to 1.5 so that a sufficiently wide range could be used. However, this is an example, and the present invention is not limited to this example.
[0036]
Next, a method of obtaining the offset value will be described with reference to FIG. FIG. 3 shows the correspondence of the A / D conversion digital code to the transmission power. In the figure, the solid line indicates the correspondence between the A / D converted digital code and the transmission power of the original reference value, and the broken line indicates the deviation (offset).
[0037]
In the correspondence shown in FIG. 3, the respective A / D conversion digital codes (P) and (Q) corresponding to, for example, the highest value and the lowest value of the transmission power in the detection range are observed, and the two points (P) and (P) are observed. Q), the difference between the value read from the curve parallel to the curve for the reference value transmission power and the A / D conversion digital code for the reference value transmission power can be set as the offset value.
[0038]
Next, a specific example of calculating an offset value from an average value of two points will be described. When the transmission power is 24 dBm (highest value), the reference value (P ′) of the A / D conversion digital code is 200, and when the transmission power is 10 dBm (lowest value), the reference value of the A / D conversion digital code (P ′) is Assuming that Q ′) is 120, the average value of the reference values is calculated as follows.
{200 (P ′ point) +120 (Q ′ point)} / 2 = 160
[0039]
When the transmission power is 24 dBm (highest value), the actual measurement value (P) of the A / D conversion digital code is 245, and when the transmission power is 10 dBm (lowest value), the actual measurement value (Q) of the A / D conversion digital code is ) Is 140, the average value of the actually measured values (the average value of the offsets) is calculated as follows.
{245 (point P) +140 (point Q)} / 2 = 193
[0040]
Assuming that the current reference voltage of the adder circuit 7-2 is 1.25 V and the accuracy of the A / D converter 7-3 is 6.64 mV / code, the adjusted reference voltage is calculated as follows. To set.
1.25V + {(160-193) × 6.64mV} = 1.031V
[0041]
In the above equation, (160-193) represents an error amount of the offset code from the reference value, and a voltage obtained by multiplying the error amount by the accuracy of the A / D converter per code of 6.64 mV is added to or subtracted from the reference voltage. By doing so, an output free from offset is obtained. That is, by changing the output voltage of the analog voltage control circuit (electronic volume) 1-1 to 1.031 V, an APC table in which the input range of the A / D converter is equal to the reference value can be obtained.
[0042]
Next, a second embodiment of the present invention is shown in FIG. The circuit configuration is substantially the same as the embodiment shown in FIG. 1 described above, and the same components are denoted by the same reference numerals. In the second embodiment, instead of a configuration in which a bias voltage corresponding to an offset error value obtained by a method similar to that of the above-described embodiment is added to the reference voltage of the operational amplifier OP2 of the adder circuit 7-2, A / A The configuration is such that the reference voltage of the D converter 7-3 is supplied.
[0043]
That is, as shown in FIG. 4, the analog voltage control circuit (electronic volume) 4-1 is added to the reference voltage of the A / D converter 7-3, and the offset code is supplied to the analog voltage control circuit (electronic volume) 4-1. Then, the input voltage of the A / D converter 7-3 is adjusted so that the input voltage does not cause a deviation (offset) from the original reference value.
[0044]
In the above-described embodiment in which the reference voltage of the operational amplifier OP2 of the adder circuit 7-2 is adjusted, it is necessary to include the gain in the calculation of the reference voltage, so that it is difficult to obtain the offset error value. However, in the second embodiment in which the reference voltage of the A / D converter 7-3 is adjusted, the offset error value with respect to the reference value is directly used as input to the analog voltage control circuit (electronic volume control) 4-1. There is an advantage that the range of the input voltage of the / D converter 7-3 can be adjusted.
[0045]
Next, a specific example of the offset compensation operation when the present invention is applied to a wireless device for a mobile wireless terminal will be described with reference to FIG. FIG. 5 shows a RACH (Random Access Channel) transmission format in a W-CDMA mobile radio communication system. The RACH is an uplink common channel used for transmitting control information and user data, to which random access is applied, and used for low-rate data transmission from an upper layer.
[0046]
The transmission power at the time of this RACH transmission is detected to obtain an offset error value, the reference voltage of the transmission power detection circuit is adjusted so that the offset error value becomes zero, and communication of user data is performed by a DCH (Dedicated Channel). Before starting, the communication is adjusted so that the communication is started without any offset error. By doing so, APC (automatic transmission power control) with high accuracy can be always performed by removing offset errors caused by aging and power supply fluctuations.
[0047]
(Supplementary Note 1) In a communication device that performs transmission power control based on a digital code obtained by converting the output voltage of a transmission power detection circuit from an analog signal to a digital signal, an offset error of the output voltage of the transmission power detection circuit with respect to a reference value. An analog voltage control circuit configured to convert an offset error read from a digital code obtained by converting an output voltage of the transmission power detection circuit into a digital signal into an analog voltage; Communication equipment having an offset compensation function of a transmission power detection circuit, comprising: means for feeding back to a reference voltage of an operational amplifier in a power detection circuit to compensate for the offset error.
(Supplementary Note 2) In a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of a transmission power detection circuit from an analog signal to a digital signal, the output voltage of the transmission power detection circuit may be an offset error with respect to a reference value. And an analog voltage control circuit for converting an offset error read from a digital code obtained by converting an output voltage of the transmission power detection circuit into a digital signal into an analog voltage, wherein an output voltage of the analog voltage control circuit is converted to the analog voltage. A communication device having an offset compensation function of a transmission power detection circuit, comprising: means for feeding back a reference voltage of an A / D converter for converting a signal to a digital signal to compensate for the offset error.
(Supplementary Note 3) A memory which stores the offset error value observed in advance and means for providing the offset error value stored in the memory to the analog voltage control circuit together with an initial set value when power is turned on. A communication device having an offset compensation function of the transmission power detection circuit according to Supplementary Note 1 or 2.
(Supplementary Note 4) The transmission power in the transmission of the control information immediately before the start of the user data transmission is detected by the transmission power detection circuit, and an offset error read from a digital code obtained by converting the detected analog voltage into a digital signal is determined by the analog voltage. 4. A communication device having an offset compensation function for a transmission power detection circuit according to any one of supplementary notes 1, 2 and 3, further comprising a means for providing the control signal to the control circuit.
(Supplementary Note 5) There is provided means for giving an offset error value different for each frequency band of the transmission signal to the analog voltage control circuit based on a digital code obtained by converting the output voltage of the transmission power detection circuit from an analog signal to a digital signal. A communication device having an offset compensation function for a transmission power detection circuit according to any one of supplementary notes 1 to 4, characterized in that:
(Supplementary Note 6) In an offset compensation method for a transmission power detection circuit in a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of the transmission power detection circuit from an analog signal to a digital signal, Calculating an offset error with respect to a reference value of the output voltage of the transmission power detection circuit from an average value of a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal with respect to the output voltage; And converting the output voltage of the analog voltage control circuit to a reference voltage of an operational amplifier in the transmission power detection circuit to compensate for the offset error. Characteristic offset compensation method for transmission power detection circuit .
(Supplementary Note 7) In an offset compensation method for a transmission power detection circuit in a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of the transmission power detection circuit from an analog signal to a digital signal, Calculating an offset error with respect to a reference value of the output voltage of the transmission power detection circuit from an average value of a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal with respect to the output voltage; Applying the output voltage of the analog voltage control circuit to the reference voltage of an A / D converter for converting the analog signal into a digital signal to compensate for the offset error. A transmission power detection circuit characterized by having Road offset compensation method.
(Supplementary Note 8) In an offset compensation method for a transmission power detection circuit in a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of the transmission power detection circuit from an analog signal to a digital signal, Calculating an offset error with respect to a reference value of an output voltage of the transmission power detection circuit from a digital code obtained by converting an output voltage of the transmission power detection circuit into a digital signal with respect to an average transmission power with respect to a value; Applying the output voltage to an analog voltage control circuit that converts the voltage into a voltage, and feeding back the output voltage of the analog voltage control circuit to a reference voltage of an operational amplifier in the transmission power detection circuit to compensate for the offset error. Offset compensation of transmission power detection circuit characterized by Atonement method.
(Supplementary note 9) In an offset compensation method for a transmission power detection circuit in a communication device that performs transmission power control based on a digital code obtained by converting the output voltage of the transmission power detection circuit from an analog signal to a digital signal, Calculating an offset error with respect to a reference value of an output voltage of the transmission power detection circuit from a digital code obtained by converting an output voltage of the transmission power detection circuit into a digital signal with respect to an average transmission power with respect to a value; Applying the voltage to an analog voltage control circuit for converting the voltage to an analog voltage, and feeding back the output voltage of the analog voltage control circuit to a reference voltage of an A / D converter for converting the analog signal to a digital signal to compensate for the offset error And transmission power. Offset compensation method for the detection circuit.
[0048]
【The invention's effect】
As described above, according to the present invention, the offset error read from the digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal is converted into an analog voltage, and the operational amplifier or the operational amplifier in the transmission power detection circuit is converted. By compensating and removing the offset error by feeding back to the reference voltage of the A / D converter, the dynamic range of the A / D converter can be adjusted without considering the input voltage range of the A / D converter with respect to the offset fluctuation. Utilizing the entire range, the accuracy of one bit (one code) of the A / D converter can be improved, and the accuracy of APC (automatic transmission power control) of transmission power can be improved.
[0049]
Further, by performing a compensation for removing an offset error based on an offset error read from a digital code which is detected by detecting transmission power in transmission of control information (RACH) immediately before the start of user data transmission and converted into a digital signal, It is possible to compensate for an offset error generated due to a change or power supply fluctuation, and to always perform highly accurate automatic transmission power control (APC).
[0050]
In addition, in the automatic transmission power control (APC), when correcting an error caused by the frequency of a transmission signal, an offset error value different for each frequency band of the transmission signal is used without storing an APC table different for each frequency. By performing the frequency correction of the offset error by feeding back the reference voltage, it is not necessary to provide a large number of APC tables, and the memory can be reduced.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration example of a transmission power detection circuit according to the present invention.
FIG. 2 is a diagram illustrating a configuration example including an APC table for each frequency of a transmission signal.
FIG. 3 is a diagram illustrating a correspondence relationship between an A / D conversion digital code and transmission power.
FIG. 4 is a diagram showing a second embodiment of the present invention.
FIG. 5 is a diagram illustrating a RACH transmission format in a W-CDMA mobile radio communication system.
FIG. 6 is a diagram showing functional blocks of a mobile wireless communication device that performs transmission power control.
FIG. 7 is a diagram illustrating a configuration of a conventional transmission power detection circuit.
FIG. 8 is a diagram illustrating the relationship between the transmission power and the input voltage of the A / D converter.
[Explanation of symbols]
1-1 Analog voltage control circuit (electronic volume)
7-1 Reference value circuit
7-2 Adder circuit
7-3 A / D converter
PA transmission power amplifier
CUP directional coupler
ISO isolator
DUP frequency sharing filter
SW antenna switch
C1 capacitor
D1 First detection diode
D2 Second detection diode
LPF high frequency removal filter
R1, R2, R1 ', R2', R3, R4, R5, R5 ', R6 resistors
OP1, OP1 Operational amplifier

Claims (5)

In a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of a transmission power detection circuit from an analog signal to a digital signal,
Analog voltage control for converting an output voltage of the transmission power detection circuit from a reference value, the offset error being read from a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal, to an analog voltage Circuit,
The output voltage of the analog voltage control circuit is fed back to a reference voltage of an operational amplifier in the transmission power detection circuit, and the offset compensation function of the transmission power detection circuit is provided. Communication equipment. In a communication device that performs transmission power control based on a digital code obtained by converting an output voltage of a transmission power detection circuit from an analog signal to a digital signal,
Analog voltage control for converting an output voltage of the transmission power detection circuit from a reference value, the offset error being read from a digital code obtained by converting the output voltage of the transmission power detection circuit into a digital signal, to an analog voltage Circuit,
A transmission power detection circuit comprising means for feeding back an output voltage of the analog voltage control circuit to a reference voltage of an A / D converter for converting the analog signal into a digital signal to compensate for the offset error. Communication equipment having an offset compensation function. 2. The memory according to claim 1, further comprising: a memory storing the offset error value observed in advance, and a unit configured to supply the offset error value stored in the memory to the analog voltage control circuit together with an initial setting value when power is turned on. 3. A communication device having an offset compensation function of the transmission power detection circuit according to 2. The transmission power in the transmission of the control information immediately before the start of the user data transmission is detected by the transmission power detection circuit, and an offset error read from a digital code obtained by converting the detected analog voltage into a digital signal is given to the analog voltage control circuit. The communication device having an offset compensation function of the transmission power detection circuit according to claim 1, wherein the communication device has means. Means for providing a different offset error value for each frequency band of the transmission signal to the analog voltage control circuit based on a digital code obtained by converting the output voltage of the transmission power detection circuit from an analog signal to a digital signal. A communication device having an offset compensation function for the transmission power detection circuit according to any one of claims 1 to 4.

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