JP3872002B2 - Transmission output control circuit - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to automatic gain control, and more particularly to a transmission output control circuit that outputs a stable high-frequency signal.
[0002]
[Prior art]
FIG. 4 is a diagram showing a conventional transmission output control circuit. A variable gain amplifier 1A that inputs a high-frequency signal and supplies an output to the antenna unit 3A, a first strip line 21A that constitutes a directional coupler, and a first strip line 21A that are coupled to the ground and have a resistor 4A between them. 2 stripline 22A, a detection diode 5A connected to the second stripline 22A, and an automatic transmission power control unit (ALC circuit) 6A connected to the detection diode 5A and controlling the variable gain amplifier 1A. The
[0003]
In the transmission output control circuit shown in FIG. 4, the input high-frequency signal is amplified by the variable gain amplifier 1A, passes through the first stripline 21A of the directional coupler 2A, and is output to the antenna unit 3A. .
Here, the second strip line 22A in the directional coupler 2A arranged parallel to the first strip line 21A on the plane is terminated at one end by the terminating resistor 4A so as to obtain the maximum coupling amount. It is configured. However, the coupling amount at this time is determined by the gap width W between the first strip line 21A and the second strip line 22A.
[0004]
It is known that if the gap width W is small, the coupling becomes honey and the coupling amount increases, but the insertion loss increases. Conversely, if the gap width W decreases, the coupling amount decreases and the insertion loss can be reduced. is there.
[0005]
Therefore, in the conventional transmission output control circuit, the gap width is set so that the insertion loss is minimized in order to minimize the power consumption. However, since the coupling amount is insufficient, the output of the variable gain amplifier is not sufficient. When the level is low, the linearity is poor (refer to the characteristic of the second strip line in FIG. 2), and the voltage output from the ALC circuit 6A to the variable gain amplifier 1A does not become a high-accuracy voltage. There is a problem that the power transmitted from the antenna unit cannot be set and becomes unstable.
[0006]
For this reason, there has been proposed a technique in which a high frequency signal branched from strip lines having different degrees of coupling depending on the magnitude of the high frequency signal is used for output level control using three strip lines (see Patent Document 1).
FIG. 5 is a diagram showing the configuration of such another conventional example. This transmission output control circuit includes a variable resistance attenuator 10B, strip lines 11B, 12B, and 13B, a switch 14B, a detection circuit 15B, a counter 16B, and the like. Using a stripline coupler having two striplines 12B and 13B coupled to a stripline 11B through which a high-frequency signal passes, using a branch signal from the stripline 12B having a low degree of coupling when transmitting normal power, power down In some cases, the switch 14B is switched so as to use a branch signal from the stripline 13B having a high degree of coupling, the detection is performed by the detection circuit 15B, and the variable resistance attenuator 10B is controlled via the counter 16B to widen the dynamic range. .
[0007]
[Patent Document 1]
Japanese Patent Laid-Open No. 2000-209108
[Problems to be solved by the invention]
The conventional transmission output control circuit with a single stripline feedback configuration has a large difference in the signal level of the feedback signal between the case where the output level of the high frequency signal is large and the case where the output level is small. The transmission output is automatically controlled by the characteristics of the detection diode. There is a problem that the control signal to be controlled becomes nonlinear and the transmission output becomes unstable.
[0009]
Further, as shown in FIG. 5, the one using the directional coupler having two strip lines for feedback improves the linearity, but the degree of coupling which is not used at the time of large transmission output is improved. There is a problem that the power consumption of the transmission output control circuit increases due to insertion loss due to a large strip line.
[0010]
(the purpose)
An object of the present invention is to provide a transmission output control circuit capable of transmitting a signal from an antenna at a stable transmission power level in a transmission output control circuit that requires high power output control.
An object of the present invention is to provide a transmission output control circuit that can output transmission power controlled with higher accuracy from an antenna unit in a transmission circuit that requires large transmission output control.
It is an object of the present invention to provide a transmission output control circuit that has a high-power and low-power coupler, so that the linearity of detection characteristics is always good, and the insertion loss of the coupler at high power can be minimized. It is to provide.
[0011]
[Means for Solving the Problems]
A transmission output control circuit according to the present invention is a transmission output control circuit that selectively outputs a high-frequency signal that is greater than or equal to a predetermined level or less than the predetermined level from a variable output control circuit. A first strip line that allows a high-frequency signal to pass through, a second strip line that is coupled to the first strip line and branches the high-frequency signal at a predetermined degree of coupling, and a first strip line that is coupled to the first strip line. A third strip line that branches the high-frequency signal with a degree of coupling greater than that of the two strip lines; a termination resistor connected between one end of the second strip line and the ground level; and a second strip line connected to the other end 1 detector diode, and when the high-frequency signal is equal to or higher than the predetermined level, both ends of the third strip line are connected to the ground level, Switching means for switching so that one end of the third strip line is connected to the ground level via a terminating resistor and the other end is connected to the second detection diode when the high-frequency signal is less than the predetermined level; And an ALC circuit that controls the variable output control circuit by a detection output that is output by DC connection of terminals on the detection output side of the first detection diode and the second detection diode .
[0012]
The ALC circuit compares a detection output by the first detection diode or the second detection diode with an automatic control threshold value set according to whether the high-frequency signal is equal to or higher than a predetermined level or lower than a predetermined level. A differential amplifier is provided.
[0013]
The transmission output control circuit of the present invention is a transmission output control circuit of a mobile communication device including an automatic transmission power control unit having a large control level,
A variable gain amplifier that can change the gain of an input high-frequency signal by a DC control voltage input from the outside and change an output level;
A first strip line that passes the output of the variable gain amplifier and outputs it to the antenna unit;
A second strip line that is parallel to the first strip line and outputs a high-frequency signal with a certain amount of coupling by a high-frequency signal passing through the first strip line. A second strip line connected to one end of a first detection diode for converting the high-frequency signal to a DC voltage at the other end,
When the both ends of the first strip line are three-dimensionally parallel and not at the ground level, the high-frequency signal passing through the first strip line is converted to a high-frequency signal with a certain amount of coupling larger than the second strip line. A third strip line to be output, having a switch capable of switching between a ground level and a terminating resistor at one end and a second strip line for converting the ground level and the high-frequency signal into a DC voltage at the other end. A third stripline having a switcher capable of switching between a terminal connected to one end of the detector diode;
When the high-frequency signal is equal to or higher than the predetermined level, both ends of the third strip line are connected to the ground level, and when the high-frequency signal is lower than the predetermined level, one end of the third strip line is set to the ground level. Switching means for switching the switch so as to connect and connect the other end to the second detection diode;
The DC voltage output from the other DC-connected other ends of the first detection diode and the second detection diode is compared with a predetermined threshold value according to the designated transmission power and transmitted. And an ALC circuit that controls the DC control voltage so that an appropriate transmission power is output from the antenna to the variable gain amplifier.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Next, a first embodiment of the transmission output control circuit of the present invention will be described in detail.
[0015]
(Description of configuration)
FIG. 1 is a diagram showing the configuration of the first exemplary embodiment of the present invention. The present embodiment is configured to increase the linearity and transmission efficiency of the transmission signal by switching the circuit configuration depending on whether the output level of the transmission power to be transmitted by supplying the high-frequency signal to the antenna unit 3 is large or small. This is a transmission output control circuit applicable to the mobile communication equipment and the like. The circuit configuration of the present embodiment is as follows.
[0016]
As shown in FIG. 1, the configuration of this embodiment includes a variable gain amplifier 1 that amplifies a high-frequency signal, an ALC circuit 10 that outputs a gain control signal of the variable gain amplifier 1, a first strip line 21, and a first strip line 21. A directional coupler 2 composed of two strip lines 22 and a third strip line 23, an antenna unit 3, a transmission power large / small control circuit 4 that switches the circuit configuration according to the magnitude of the transmission power, and 2 It comprises two switches 6 and 11 and two diodes 8 and 9 for detecting high frequency signals.
[0017]
The detailed configuration and function of each part are as follows.
The variable gain amplifier 1 can change the gain of the input high-frequency signal by a DC control voltage input from the outside (ALC circuit 10), changes the output level according to the DC control voltage, and directs the amplified high-frequency signal to the direction. Output to the first strip line 21 of the sex coupler 2.
[0018]
The directional coupler 2 includes a second strip line 22 and a third strip line 23 in which the planes of the strip lines are arranged in parallel so as to be coupled to the first strip line 21, and the first strip Based on the high-frequency signal passing through the line 21, the high-frequency signal is output with different coupling amounts. One end of the second strip line 22 is connected to the diode 9, and the other end is connected to the ground level via the terminating resistor 5 so as to obtain the maximum amount of coupling. Both ends of the third strip line 23 are connected to the switch 6 and the switch 11, respectively.
[0019]
Here, the coupling amount can be set by the interval between the strip lines arranged in parallel, and in this embodiment, the coupling amount of the second strip line 22 with respect to the first strip line 21 is about 20 dB. Yes, the coupling amount of the third strip line 23 to the first strip line 21 is set to about 10 dB.
[0020]
The switch 6 is a change-over switch that can be switched between a terminal that connects one end of the third strip line 23 to the ground (ground) level via the termination resistor 7 and a terminal that is directly connected to the ground level. The switch 11 is a change-over switch that switches between a terminal connected to the ground level at the other end of the third strip line 23 and a terminal connected directly to the ground level. The switches 6 and 11 are synchronously switched between the switches 6 and 11 to the position shown in FIG. 1 or the opposite position by the control from the transmission power large / small control circuit 4.
[0021]
As a result, when the transmission power is large (transmission power “high”), the switches 6 and 11 connect one end of the third strip line 23 to the ground level by the control from the transmission power large / small control circuit 4. Connect the other end to the ground level. In this state, the insertion loss of the third strip line 23 having a large insertion loss due to a large coupling amount is set to the minimum. The first diode 9 is connected to one end of the second strip line 22, detects a high frequency signal induced in the second strip line 22 by coupling, and converts the high frequency signal into a DC voltage (detection output). And output to the ALC circuit 10.
[0022]
When the transmission power is small (transmission power “low”), the switches 6 and 11 are connected to the one end of the third strip line 23 via the termination resistor 7 under the control of the transmission power high / low control circuit 4. The other end is connected to the second diode 8 for detection. In this state, the second diode 8 detects the high-frequency signal induced in the third strip line 23 via the switch 11, converts the high-frequency signal into a DC voltage (detection output), and outputs it to the ALC circuit 10. To do. At this time, the DC voltage output from the second detection diode 8 is added to the DC voltage output from the first detection diode 9, and then output to the ALC circuit 10, but the second and third striplines Since the detection output of the diode 8 is larger than the detection output on the diode 9 side due to the difference in coupling amount, the diode 9 is reverse-biased and the detection operation is stopped.
[0023]
The ALC circuit 6 inputs the detection outputs of the first or second diodes 9 and 8 according to the control signal from the transmission power large / small control circuit 4 corresponding to the transmission power “large” or “small”, respectively. And a differential amplifier that compares with a preset threshold value, and outputs the difference as a DC control voltage of the gain of the variable gain amplifier 1 so that appropriate transmission power is output from the antenna. To do.
[0024]
(Description of operation)
The operation of the present embodiment will be described in detail with reference to FIGS. In this embodiment, the circuit operation differs depending on whether the transmission power transmitted from the antenna unit is large or small. The operation will be described below according to the magnitude of transmission power.
(Operation when transmission power is large)
In the present embodiment, when a large transmission power (transmission power “high”) is transmitted from the antenna unit, the following operation is performed.
The transmission power large / small control circuit 4 switches the selector switch to a state opposite to that shown in the figure by a switching control signal for the switches 6 and 11. At the same time, the threshold value Vref of the ALC circuit 10 is set to a value corresponding to the detection voltage value output from the diode 9 side with a large transmission power value.
[0025]
A high frequency signal is input to the variable gain amplifier 1, and the amplified high frequency signal passes through the first strip line 21 in the directional coupler 2 and is output to the antenna unit 3. Since the gap between the first strip line 2 and the second strip line 3 and the gap value are set so that the coupling amount is about 20 dB, the second strip line 22 includes the first strip line 22. Induces a transmit power that is about 20 dB down from.
[0026]
The first detection diode 9 connected to the second strip line 22 detects the transmission power and converts it into a DC voltage, which is input to the ALC circuit 10. Note that the second diode 8 is disconnected from the third strip line 23 by the switch 11, and the detection output is zero.
[0027]
The ALC circuit 10 has a threshold value set in advance corresponding to the transmission power “high” transmitted from the antenna, and the amplification factor of the variable gain amplifier 1 is set so that the input DC voltage is the same as the threshold value. By outputting a DC voltage for variably controlling (gain), the output of the transmission power “high” from the antenna unit 3 is kept constant. The configuration and operation of the ALC circuit 10 are realized with known ones.
[0028]
In the above operation, the switch 6 and the switch 11 arranged at both ends of the third strip line 23 arranged in parallel to the first strip line 21 in the vertical direction are connected to both ends by the transmission power large / small signal. Fixed to ground level.
(Operation when transmission power is low)
Next, when a small transmission power (transmission power “low”) is transmitted from the antenna, the operation is as follows.
The transmission power large / small control circuit 4 switches the changeover switch to the state shown in the figure by a changeover control signal for the changers 6 and 11. That is, the switches 6 and 11 have one end of the third strip line 23 connected to the ground level via the termination resistor 7 and the other end connected to the second detector diode 8. At the same time, the threshold value Vref of the ALC circuit 10 is set to a value corresponding to the detection voltage value output from the diode 8 side with a small transmission power value.
[0029]
A high frequency signal is input to the variable gain amplifier 1, and the amplified high frequency signal passes through the first strip line 21 in the directional coupler 2 and is output to the antenna unit 3. Since the gap between the first strip line 21 and the third strip line 23 and the gap value are set so that the coupling amount is about 10 dB, the third strip line 23 includes the first strip line 23. Induces a transmit power that is about 10 dB lower than
[0030]
The second diode 8 is connected to the third strip line 23 by the switch 11, and the second detection diode 8 detects the transmission power and converts it into a DC voltage, and this DC voltage is the ALC circuit 10. Is input. In addition, the DC voltage from the first detection diode 9 is also input to the ALC circuit 10. However, in the operation of the transmission power “low”, the DC voltage from the second detection diode 8 is substantially reduced. Operate.
[0031]
The ALC circuit 10 is preset with a threshold value corresponding to the transmission power “low” transmitted from the antenna unit, and outputs a DC control voltage so that the input DC voltage is the same as the threshold value. By controlling the amplification degree (gain) of the variable gain amplifier 1, the output of the transmission power “low” from the antenna unit 3 is kept constant.
[0032]
FIG. 2 is a diagram showing the characteristics of the first and second detection voltages, their linearity and the insertion loss due to the second and third striplines with respect to the output level of the variable gain amplifier. Hereinafter, the characteristics of the transmission output control circuit in the operation according to the transmission power “high” and “small” of the present embodiment will be described.
[0033]
As shown in FIG. 2, on the second strip line 22 side, the coupling amount is about 20 dB, the insertion loss is as low as about 0.5 dB, and the detection voltage is low overall. Further, the detection characteristic shows good linearity in a region where the output level of the variable gain amplifier 1 is high, and shows nonlinear characteristics in a low region. On the other hand, the third stripline 23 side has a coupling amount of about 10 dB and an insertion loss as large as about 0.8 dB, but exhibits a sufficient induced voltage even in a region where the output level of the variable gain amplifier 1 is low, It can be seen that the detection characteristic can maintain the linear characteristic (linearity).
[0034]
In the present embodiment, when the transmission power is “high”, the switches 6 and 11 are switched to the configuration using the second stripline 22, and the detection voltage on the second stripline 22 side is the saturation of the diode. The characteristic shows good linearity, and the insertion loss by the second strip line 22 is also relatively low, about 0.5 dB. At this time, on the third strip line 23 side, the insertion loss has a relatively large characteristic of about 0.8 dB. However, the switches 6 and 11 are controlled by the transmission power large / small control circuit 4 so that the switches 6 and 11 can Since both ends of 23 are switched to the ground level, the insertion loss can be reduced to such an extent that it hardly affects. That is, it is possible to obtain good linearity and insertion loss characteristics at a transmission power “high”.
[0035]
When the transmission power is “low”, the switches 11 and 6 are switched to the configuration using the third strip line 23, and the insertion loss of the third strip line 23 has a relatively large characteristic of about 0.8 dB. As shown, since the coupling amount of the third strip line 23 is about 10 dB, a sufficient induced voltage is exhibited even in a region where the output level is low. Indicates.
[0036]
As described above, the switchers 6 and 11 are switched at the switching point in FIG. 2 according to the control signal from the transmission power large / small control circuit, and the transmission power from the small transmission power is transmitted by using the third stripline 23 together. It is possible to achieve excellent linearity characteristics in the entire “large” region and to reduce the influence of insertion loss due to the provision of the third stripline 23 in the region of “large” transmission power.
[0037]
(Other embodiments)
In the above embodiment, the example in which the directional coupler is used as the means for generating the feedback signal has been described. However, the feedback circuit can be configured by using a coupling capacitor instead of the directional coupler. .
[0038]
FIG. 3 is a diagram illustrating a configuration example of the second embodiment. Blocks with the same symbol have the same function. Hereinafter, the second embodiment will be described in detail.
[0039]
In the present embodiment, a switch 20 provided at the output of the variable gain amplifier circuit 1, and a coupling capacitor 24 and a detector between the two contacts on the output side of the switch 20 and the input of the ALC circuit 10, respectively. And a series circuit of a coupling capacitor 25 and a detection diode 27 are provided. Here, the constant of the coupling capacitor 24 is set so that the coupling amount is about 20 dB, and the constant of the coupling capacitor 25 is set so that the coupling amount is about 10 dB.
[0040]
(Operation when transmission power is large)
In the second embodiment, when large transmission power (transmission power “high”) is transmitted from the antenna, the following operation is performed.
The transmission power large / small control circuit 4 controls the switcher 20 according to the control signal to switch the output of the signal variable gain amplifier 1 to the coupling capacitor 24. Further, the ALC circuit 10 is controlled, and the reference voltage Vref is set to a large threshold value corresponding to the transmission power “high”. The output of the coupling capacitor 24 outputs transmission power that is about 20 dB lower than the output of the variable gain amplifier 1, and the first diode 26 performs a detection operation in a highly linear region and converts a high-frequency signal into a DC voltage. Output.
[0041]
The DC voltage output from the first detection diode 26 is input to the ALC circuit 10 so that the ALC circuit 10 is equal to the threshold value corresponding to the transmission power “high” transmitted from the antenna 3 in advance. The DC control voltage is output to the variable gain amplifier 1, and the transmission power output from the antenna 3 is kept constant by the negative feedback operation.
[0042]
As described above, in the transmission output control circuit according to the present embodiment, the variable gain amplifier 1 varies the amplification degree by the DC voltage output from the ALC circuit 10, and the input high frequency signal is set to a constant output level from the antenna unit 3. Send. Here, the transmission output control circuit is not affected by loss due to the other capacitor 25 and diode 27.
[0043]
(Operation when transmission power is low)
In the second embodiment, when a small transmission power (transmission power “low”) is transmitted from the antenna, the operation is as follows.
The transmission power large / small control circuit 4 controls the switcher 20 by the control signal to switch the output of the signal variable gain amplifier 1 to the coupling capacitor 25. Further, the ALC circuit 10 is controlled, and the reference voltage Vref is set to a small threshold value corresponding to the transmission power “low”. The output of the coupling capacitor 25 outputs transmission power that is about 10 dB lower than the output of the variable gain amplifier 1, and the second diode 27 performs a detection operation in a highly linear region and converts a high-frequency signal into a DC voltage. Output.
[0044]
The DC voltage output from the second detection diode 27 is input to the ALC circuit 10 so that the ALC circuit 10 is equal to the threshold value corresponding to the transmission power “low” transmitted from the antenna unit 3 in advance. In addition, a DC voltage is output to the variable gain amplifier 1 and the transmission power output from the antenna 3 is kept constant.
[0045]
As described above, in the transmission output control circuit according to the present embodiment, the variable gain amplifier 1 varies the amplification degree according to the DC control voltage output from the ALC circuit 10, and the input high frequency signal is set as a constant output level from the antenna 3. Send. Here, the transmission output control circuit is not affected by loss due to other capacitors 24 and diodes 26.
[0046]
【The invention's effect】
According to the present invention, by using a coupling circuit such as a directional coupler for high power and low power, detection characteristics with high linearity can be used to generate a DC control voltage for gain control of a variable gain amplifier. Therefore, transmission power with high linearity can be controlled from a large transmission output to a small transmission output, and accurate transmission power can be transmitted from the antenna unit.
[0047]
In addition, the insertion loss due to coupling of the coupling portion of the low power coupling circuit is reduced by substantially reducing the influence of the coupling portion of the coupling circuit for small power when the coupling amount is large. Since the insertion loss of the coupling portion of the coupling circuit at the time of high power can be minimized, the power consumption of the variable gain amplifier can be minimized. In addition, since the insertion loss can be minimized, the power output from the variable gain amplifier can be reduced, so that the current consumption of the variable gain amplifier can be kept low.
[0048]
Note that a directional coupler (strip line coupler) is used as a coupling circuit so that a high-frequency signal can be supplied to the antenna unit through the strip line, and the variable gain amplifier and the antenna can be supplied by the strip line coupler. It is also possible to provide a matching function with the part side.
[0049]
Furthermore, since a directional coupler can be configured in three dimensions by using a microstrip coupler, a configuration using the surface layer and inner layer of the printed board can be adopted, and the mounting area can be minimized, so that the transmission output can be minimized. It is possible to reduce the size when the control circuit is formed of a printed board.
[Brief description of the drawings]
FIG. 1 is a diagram showing a first embodiment of the present invention.
FIG. 2 is a diagram illustrating characteristics of the feedback circuit according to the first embodiment.
FIG. 3 is a diagram showing a second embodiment of the present invention.
FIG. 4 is a diagram showing a conventional example.
FIG. 5 is a diagram showing another conventional example.
[Explanation of symbols]
1 variable gain amplifier 2 coupling circuit 21 first strip line 22 second strip line 23 third strip line 24 first capacitor 25 second capacitor 26 first diode 27 second diode 3 antenna unit 4 transmission Electric power large / small control circuit 6, 11, 20 switch 7 resistor 8, 9 detector diode 10 ALC circuit

Claims (3)

A transmission output control circuit that selectively outputs a high-frequency signal that is greater than or equal to a predetermined level or less than the predetermined level from a variable output control circuit,
A first strip line for passing a high-frequency signal output from the variable output control circuit;
A second stripline coupled to the first stripline and branching the high frequency signal at a predetermined degree of coupling;
A third stripline that is coupled to the first stripline and branches the high-frequency signal with a degree of coupling greater than that of the second stripline;
A termination resistor connected between one end of the second stripline and the ground level and a first detection diode connected to the other end;
When the high-frequency signal is equal to or higher than the predetermined level, both ends of the third strip line are connected to the ground level, and when the high-frequency signal is lower than the predetermined level, one end of the third strip line is connected to a termination resistor. Switching means for switching to connect to the ground level via the other end and to connect the other end to the second detection diode;
An ALC circuit that controls the variable output control circuit by a detection output that is output by DC connection of terminals on the detection output side of the first detection diode and the second detection diode;
A transmission output control circuit comprising: The ALC circuit compares a detection output from the first detection diode or the second detection diode with an automatic control threshold set in accordance with whether the high-frequency signal is equal to or higher than a predetermined level or lower than a predetermined level. The transmission output control circuit according to claim 1, further comprising a differential amplifier . A transmission output control circuit of a mobile communication device having an automatic transmission power control unit with a large control level,
A variable gain amplifier that can vary the gain of an input high-frequency signal by a DC control voltage input from the outside and can change an output level;
A first strip line that passes the output of the variable gain amplifier and outputs it to the antenna unit;
A second strip line that is parallel to the first strip line and outputs a high-frequency signal with a certain amount of coupling by a high-frequency signal passing through the first strip line. A second strip line connected to one end of a first detection diode for converting the high-frequency signal into a DC voltage at the other end;
When the both ends of the first strip line are three-dimensionally parallel and not at the ground level, the high-frequency signal passing through the first strip line is converted to a high-frequency signal with a certain amount of coupling larger than the second strip line. A third strip line to be output, having a switch capable of switching between a ground level and a terminating resistor at one end, and a second strip line for converting the ground level and the high-frequency signal into a DC voltage at the other end. A third stripline having a switch capable of switching between a terminal connected to one end of the detector diode;
When the high-frequency signal is equal to or higher than the predetermined level, both ends of the third strip line are connected to the ground level, and when the high-frequency signal is lower than the predetermined level, one end of the third strip line is set to the ground level. Switching means for switching the switch so as to connect and connect the other end to the second detection diode;
The DC voltage output from the other DC-connected other ends of the first detection diode and the second detection diode is compared with a predetermined threshold value according to the designated transmission power and transmitted. An ALC circuit that determines the amount of power that is present and controls the DC control voltage so that an appropriate transmission power is output from the antenna to the variable gain amplifier;
A transmission output control circuit comprising:

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