JP3010130B2 - Transmission power control method and transmission power control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission power control method and a transmission power control device for controlling the transmission power of a transmission device connected to an antenna via an antenna matching device.

[0002]

2. Description of the Related Art Conventionally, when designing an antenna matching device for matching the impedance between an antenna and a transmitting device, circuit components (for example, a variable inductor, a variable capacitor, a high-frequency relay, etc.) in the antenna matching device include:
Consideration is made so that the transmission power of the transmission device does not cause damage. Specifically, the impedance of the antenna at the transmission frequency is measured or calculated, the maximum transmission power of the transmission device is defined, and when the maximum transmission power is input to the antenna matching device, the applied high-frequency voltage or Circuit components that can withstand high-frequency currents. Then, in the conventional transmission power control method for controlling the transmission power of the transmission device, the transmission power of the transmission device is controlled so as not to exceed the maximum transmission power described above.

[0003]

However, the antenna may be damaged by, for example, a lightning strike, and as a result, the impedance of the antenna may change. In such a case, the conventional transmission power control method has the following problems. In other words, even when the same transmission power as before the antenna was damaged is output to the antenna matching device, if the antenna impedance is higher than before the damage, the circuit components in the antenna matching device are connected. When the applied high-frequency voltage increases and the antenna impedance decreases, the high-frequency current passing through each circuit component increases. As a result, during the matching operation by the antenna matching device, when the transmitting device outputs the same maximum transmission power to the antenna matching device as before the antenna is damaged, the high-frequency voltage or the high-frequency current applied to the antenna matching device becomes the maximum of each circuit component. The allowable applied voltage or the maximum allowable passing current may be exceeded. In such a case, there is a problem that each circuit component is damaged. In this case, the antenna matching device is generally attached to the end of the antenna. Therefore, when the antenna is stretched in the air using the antenna tower, an extremely dangerous operation is required because the antenna matching device must be repaired on the antenna tower.

[0004] On the other hand, during matching operation, it is conceivable to reduce the transmission power of the transmitting device and transmit at normal transmission power after matching, but after all, when transmitting at normal transmission power, the maximum of each circuit component is considered. Since the allowable applied voltage or the maximum allowable passing current is exceeded, the antenna matching device may be damaged. On the other hand, if the antenna impedance is measured again after the antenna is damaged, the transmission power that does not damage each circuit component is obtained, and the transmission power is transmitted at the transmission power or less, the above-described problem can be solved. However, when it is necessary to transmit urgently, such as in a disaster, there is no time to measure the antenna impedance each time. May also be damaged.

The present invention has been made in view of such a problem, and even if the impedance of the antenna is unknown, it is possible to operate the transmission device without damaging circuit components in the antenna matching device. It is an object to provide a transmission power control method and a transmission power control device.

[0006]

In order to achieve the above object,
A transmission power control method according to claim 1 is a transmission power control method for controlling a transmission power of a transmission device connected to an antenna via an antenna matching device, wherein the transmission power control method is based on an antenna matching device for matching the antenna and the transmission device. During alignment operation,
After the transmission power of the transmitting device is reduced, and after the matching operation is completed, the antenna voltage applied to the antenna and the antenna current flowing through the antenna are respectively detected in a state where the transmission power is reduced. On the basis of,
The maximum transmission power that does not exceed the antenna voltage and the antenna current allowed by the antenna matching device is calculated, and the transmission power of the transmission device after the matching operation is controlled to be equal to or less than the calculated maximum transmission power. It is characterized by the following.

According to a second aspect of the present invention, in the transmission power control method according to the first aspect, the power of the extraneous wave induced in the antenna is detected before the matching operation is completed.
Based on the detected extraneous wave power, determine the transmission power at the time of the matching operation of the transmitting device at the time of the matching operation, at the time of the matching operation,
The transmission power of the transmitting apparatus is controlled so as to become the determined transmission power at the time of the matching operation.

According to a third aspect of the present invention, there is provided a transmission power control apparatus connected to an antenna via an antenna matching device and controlling the transmission power of a transmission apparatus whose maximum transmission power is regulated by a transmission power control signal. And an antenna voltage detecting unit for detecting an antenna voltage applied to the antenna, an antenna current detecting unit for detecting an antenna current flowing to the antenna, and matching by an antenna matching device for matching the antenna and the transmitting device. During operation, a transmission power control unit that reduces the transmission power of the transmission device by a transmission power control signal, and after the matching operation is completed,
Based on the detection results of the antenna voltage detection unit and the antenna current detection unit in a state where the transmission power is reduced, the maximum transmission power that does not exceed the antenna voltage and the antenna current allowed by the antenna matching device is calculated. A transmission power calculation unit, wherein the transmission power control unit includes:
The transmission power control signal is output to the transmission device such that the transmission power of the transmission device after the matching operation is equal to or less than the calculated maximum transmission power.

According to a fourth aspect of the present invention, there is provided the transmission power control apparatus according to the third aspect, wherein an extraneous wave power detection unit for detecting the power of the extraneous wave induced in the antenna, and the detected extraneous wave power A matching operation transmission power determining unit that determines a matching operation transmission power of the transmission device at the time of the matching operation, wherein the transmission power control unit determines the transmission device transmission power during the matching operation. A transmission power control signal which becomes transmission power at the time of matching operation is output to the transmission device.

[0010]

According to the transmission power control method of the present invention, the transmission power of the transmission device is reduced during the matching operation by the antenna matching device, so that the transmission power exceeding the antenna voltage or antenna current allowed by the antenna matching device is reduced. It is not entered into the device. Also, at the time of matching operation,
The antenna voltage applied to the antenna and the antenna current flowing through the antenna are detected, respectively, and the maximum transmission that does not exceed the antenna voltage and antenna current allowed by the antenna matching device is determined based on the results of both detections. The power, that is, the maximum transmission power that does not damage the circuit components in the antenna matching device, is calculated as the calculated maximum transmission power. Then, the transmission power of the transmission device after the matching operation is controlled to be equal to or less than the calculated maximum transmission power.

As described above, the transmission power of the transmission device is controlled so that the antenna matching device is not damaged.
Even if the antenna is damaged and the impedance changes, without damaging the antenna matching device,
Immediately, the matching operation can be performed and the transmission can be started.

In the transmission power control method according to the second aspect, before the matching operation is completed, the power of the extraneous wave induced in the antenna is detected, and the transmission power during the matching operation is determined based on the detected extraneous wave power. To determine. In this case, the transmission power at the time of the matching operation is determined to be several times the power of the extraneous wave, for example, so that the extraneous wave does not affect the matching operation. Then, at the time of the matching operation, the transmission power of the transmitting apparatus is controlled so as to become the determined transmission power at the time of the matching operation. As a result, at the time of the matching operation, damage to the antenna matching device is prevented, and a matching error in the matching operation is prevented.

[0013] In the transmission power control apparatus according to the third aspect, at the time of the matching operation by the antenna matching apparatus for matching the antenna and the transmission apparatus, the transmission power control unit reduces the transmission power of the transmission apparatus by the transmission power control signal. Therefore, transmission power exceeding the antenna voltage or antenna current allowed by the antenna matching device is not input into the antenna matching device. Further, after the matching operation is completed, when the transmission power is reduced, the antenna voltage detection unit detects the antenna voltage applied to the antenna,
An antenna current detector detects an antenna current flowing through the antenna.

Next, the transmission power calculation section calculates the maximum transmission power that does not exceed the antenna voltage and antenna current allowed by the antenna matching device as the calculated maximum transmission power based on the two detection results. Then, during normal transmission of the transmission device after the matching operation, the transmission power control unit outputs a transmission power control signal to the transmission device such that the transmission power of the transmission device becomes equal to or less than the calculated maximum transmission power.
As described above, since the transmission power of the transmitting device is controlled so that the antenna matching device is not damaged, for example, even when the antenna is damaged and the impedance is changed, the inside of the antenna matching device is not damaged and immediately. ,
The matching operation can be performed and the transmission can be started.

In the transmission power control apparatus according to the fourth aspect, first, before the matching operation, the extraneous wave power detection unit detects the power of the extraneous wave induced in the antenna, and the matching operation-time transmission power determining unit determines The transmission power during the matching operation is determined based on the extraneous wave power detected by the extraneous wave power detection unit. In this case, the transmission power at the time of the matching operation is determined to be several times the power of the extraneous wave, for example, so that the extraneous wave does not affect the matching operation. Then, at the time of the matching operation, the transmission power of the transmitting apparatus is controlled so as to become the determined transmission power at the time of the matching operation. As a result, at the time of the matching operation, damage to the antenna matching device is prevented, and a matching error in the matching operation is prevented.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments according to the present invention will be described below in detail with reference to the drawings. FIG. 1 shows a communication system 1, which includes a transmitting device 2, an antenna matching device 3, and an antenna 4.

The transmitting device 2 is not particularly limited,
It is a wireless device capable of transmitting a high frequency signal of 0 KHz to 30 MHz, and is configured to transmit up to 300 W. Also, at the time of the first transmission after the power is turned on, the transmitting apparatus 2 outputs a matching signal to the antenna matching apparatus 3 so that the antenna 4 and its own impedance are matched by the antenna matching apparatus 3, and outputs the matching signal to the antenna matching apparatus 3. The maximum transmission power, which is the maximum transmission power that can be transmitted, is regulated by the transmission power control signal from the communication device.

The antenna matching device 3 is for automatically matching the impedance between the transmitting device 2 and the antenna 4 and includes a control unit (transmission power control unit, transmission power calculation unit, transmission power determination unit for matching operation) 11, Sanse 12, matching unit 13, voltage sensor (high-frequency voltage detection unit) 14, current sensor (high-frequency current detection unit, extraneous wave power detection unit) 15, first
A rectifier (high-frequency voltage detector) 16 and a second rectifier (high-frequency current detector, extraneous wave power detector) 17 are provided.

The control unit 11 controls the transmission power of the transmitting device 2 and the on / off of a high-frequency relay (not shown) of the matching unit 13 described later during the automatic matching operation. The transmission power of the transmission device 2 is controlled.

The sensor 12 measures the standing wave ratio between the transmitting device 2 and the antenna 4 during the automatic matching operation, and outputs the measured standing wave ratio signal to the control unit 11.

The matching section 13 is composed of a π-type circuit and includes a first variable capacitor section 21, a second variable capacitor section 22, and a variable inductor section 23. First
Variable capacitor section 21 and second variable capacitor section 22
Has a plurality of capacitors arranged in parallel between a high-frequency line and ground, and a high-frequency relay for connecting each capacitor to the high-frequency line. The capacitance of each of the capacitor units 21 and 22 can be increased or decreased stepwise by operating a high-frequency relay according to a control signal from the control unit 11. In addition, the variable inductor unit 2
Reference numeral 3 includes a plurality of coils arranged between the sensor 12 and the antenna 4 so as to be connectable in series, and a plurality of high-frequency relays for short-circuiting each coil. The variable inductor unit 23 can increase or decrease the inductance in a stepwise manner by operating a high-frequency relay according to a control signal from the control unit 11.

The voltage sensor 14 detects a high-frequency voltage applied to the second variable capacitor section 22, that is, an antenna voltage applied to the end of the antenna 4. The voltage sensor 14
The high-frequency voltage applied to the second variable capacitor unit 22 is constituted by two resistors 24 and 25,
, And outputs the divided high-frequency voltage V1 to the first rectifier 16.

The current sensor 15 includes a variable inductor 23
, Ie, an antenna current flowing through the antenna 4 is detected. The current sensor 15 includes a current transformer 26 and a resistor 27. The current transformer 26 picks up a high-frequency current flowing through a lead wire connected to the antenna 4, and the resistor 27 terminates the current transformer 26 so that the output impedance of the current transformer 26 has a constant resistance value. Further, the current sensor 15 converts the high-frequency voltage V2 represented by the product of the picked-up high-frequency current and the resistance value of the resistor 27 into the second rectifier 17.
Output to

The current sensor 15 detects the power of a foreign wave induced in the antenna 4. Specifically, the current sensor 15 outputs the high-frequency current flowing through the current transformer 26 in a direction opposite to the above-described antenna current when the transmission power is not output from the transmission device 2 to the high-frequency voltage V3 representing the external wave power. Detected as

The first rectifier 16 rectifies the high-frequency voltage V1 with a predetermined efficiency and outputs the rectified rectified voltage V11 to the controller 11. The second rectifier 17 rectifies the high-frequency voltages V2 and V3 with a predetermined efficiency, and outputs the rectified rectified voltages V12 and V13 to the controller 11.

Next, the matching process and the transmission power control process of the transmitting device 2 by the control unit 11 will be described with reference to FIG. The following operations are all executed by the control unit 11.

As shown in the figure, a matching process is performed first (step 31). Specifically, when a matching signal is output from transmitting apparatus 2, control unit 11 recognizes that matching processing is to be performed, and transmits a transmission power control signal that makes transmitting power of transmitting apparatus 2 10 W. Output to the transmission device 2. The control unit 11 stores the value of the high-frequency current flowing through the matching unit 13 when the transmission power is 10 W in the internal memory as a reference current, and sets the standing wave ratio detected by the sensor 12 to a certain value or less. The upper limit value of the standing wave ratio for detecting the quasi-matching point and the upper limit value of the current ratio for detecting the normal matching point at which the current ratio described below becomes a certain value or less are stored in internal memories, respectively. I have. Note that the value of the reference current is (10 W / output impedance of the transmission device 2).
Represented by ^0.5, for example, when the output impedance of the transmitter 2 is 50 [Omega, are substituted into the above-mentioned formula, 0.4
47A.

Next, by outputting a control signal to the matching unit 13 and operating the high-frequency relay, the capacitance of the second variable capacitor unit 22 is increased stepwise, and the inductance of the variable inductor unit 23 and the first variable capacitor The capacitance of the unit 21 is changed stepwise. At this time, while the standing wave ratio is monitored by the standing wave ratio signal output from the sensor 12, the state (the quasi-matching point described above) becomes smaller than a certain value. To detect.

Next, the current ratio is determined. This current ratio is calculated by calculating the antenna current Ia corresponding to the rectified voltage V12 output through the second rectifier 17 after being picked up by the current sensor 15, and the ratio of the antenna current Ia to the reference current (= Ia / (Reference current). If the current ratio is equal to or less than the upper limit value stored in the internal memory, the matching process is terminated as a normal matching point, and if the current ratio exceeds the upper limit value,
By changing the capacitance of the first variable capacitor section 21 and the second variable capacitor section 22 and changing the inductance of the variable inductor section 23,
A normal matching point is found, and the matching process ends. In this case, the quasi-matching point where the current ratio is equal to or less than the upper limit is regarded as the normal matching point for the following reason. That is, there are a plurality of quasi-matching points at which the standing wave ratio becomes equal to or less than a certain value by the matching unit 13 of the π-type circuit. However, the copper loss of the variable inductance unit 23 and the variable capacitor units 21 and
In order to minimize the transmission power loss due to the tangent (Tan δ) of the loss angle of the capacitor 2, the matching unit 1
The circuit Q of No. 3 must be lowered. For this reason, a quasi-matching point where the circuit Q is low, that is, a quasi-matching point where the current ratio is small is defined as a normal matching point.

Next, while maintaining the transmission power at 10 W, the rectified voltage V12 output from the second rectifier 17 is measured to measure the high-frequency current I0 flowing through the antenna 4 in the normal matching state ( Step 3
2). In this case, the high-frequency current I0 is calculated based on the degree of coupling of the current transformer 26, the rectification efficiency b of the second rectification unit 17, and the like. That is, the high-frequency current I0 (unit "A") is represented by the following equation 1. I0 = rectified voltage V12 ÷ coupling degree ÷ rectified efficiency b ÷ (resistance value of resistor 27) (Expression 1) In this case, there is a relationship of rectified voltage V12 = high-frequency voltage V2 × rectified efficiency b. The degree of coupling here is a value obtained by dividing the high-frequency current picked up by the current transformer by the high-frequency current I0.

Next, in this state, the first rectifier 1
The high-frequency voltage V0 applied to the second variable capacitor section 22 in the matching state is measured by measuring the rectified voltage V11 output from Step 6 (Step 3).
3). In this case, the high frequency voltage is calculated based on the voltage division ratio of the resistors 24 and 25, the rectification efficiency a of the first rectification unit 16, and the like. That is, the high-frequency voltage V0 (unit “V”) is
It is represented by the following equation 2. V0 = rectified voltage V11 × (resistance value of resistor 24 + resistance value of resistor 25) ÷ (resistance value of resistor 25) ÷ rectification efficiency a (Expression 2) In this case, rectified voltage V11 = high-frequency voltage V1 × rectification There is a relationship of efficiency a.

Next, it is determined whether or not the maximum transmission power based on the high frequency current I0 is larger than the maximum transmission power based on the high frequency voltage V0 (step 34). In this case, the maximum transmission power based on the high-frequency current is calculated as follows. For example, when the maximum allowable passing current of the variable inductor unit 23 is 6 A, the maximum transmission power is represented by the following Expression 3. Maximum transmission power (W) = 10 (W) × (6 ÷ high-frequency current I0) ² (Equation 3) The maximum transmission power based on the high-frequency voltage V0 is calculated as follows. That is, for example, when the maximum allowable applied voltage of the second variable capacitor unit 22 is 16000 V, the maximum transmission power is represented by the following Expression 4. Maximum transmission power (W) = 10 (W) × (16000 ÷ high frequency voltage V 0) ² (Equation 4)

If it is determined in step 34 that the maximum transmission power based on the high-frequency current I0 is larger, the transmission power of the transmitting device 2 becomes equal to or less than the maximum transmission power calculated based on the high-frequency voltage V0. A power control signal is output to the transmitting device 2 (Step 35). On the other hand, when it is determined that the maximum transmission power based on the high-frequency voltage V0 is larger, the transmission power of the transmitting device 2 is changed to the high-frequency current I0.
A transmission power control signal that is equal to or less than the maximum transmission power calculated based on
6). That is, the circuit components such as the capacitor, the coil, and the high-frequency relay used in the antenna matching device 3 are damaged when the device is used beyond at least one of the maximum allowable passing current and the maximum allowable applied voltage. Therefore, the maximum transmission power of the transmission device 2 is controlled so that the transmission power of the transmission device 2 does not exceed either of the two standards. As a result, the transmission power of the transmitting device 2 is controlled so that the maximum transmission power is within a range that does not damage the components in the antenna matching device 3 (step 37).

Note that the transmission power during the matching operation is set to 10
W (maximum 20 W) is set for the following reason. That is, the transmission power is sufficient power (for example, 1 W) to detect the standing wave ratio signal output from the sensor 12.
Degree). However, when a plurality of antennas are adjacent to each other, the transmission power transmitted by the other transmission device is input to the antenna 4, and the transmission power of the other transmission device is detected by the current sensor 15, and Sensor 14
Will also be detected. In this case, the transmission power output from the transmission device 2 cannot be accurately detected. For this reason, it is necessary to use a transmission power that is at least several times larger than the transmission power transmitted from another transmission device, and is set to 10 W in such a case. However, the present invention is not limited to this, and the transmission power can be set within a range in which circuit components in the antenna matching device 3 are assumed not to be damaged. Further, in the present embodiment, the control unit 11 lowers the transmission power for the transmission device 2, but is not limited to this, and the transmission device 2 automatically lowers the transmission power to 10 W during the matching operation. It may be configured as follows. In this case, the transmission power control device according to the present invention is built in the transmission device 2.

As described above, according to the present embodiment, when a transmission power of 10 W is output from the transmitting device 2 during the matching operation, the high-frequency current passing through the circuit components in the antenna matching device 3 is supplied to the current sensor. The voltage sensor 14 detects the high-frequency voltage applied to the circuit components, and the control unit 11 calculates the maximum transmission power that does not exceed the standards of both circuit components. Then, the control unit 11 automatically controls the transmission power of the transmission device 2 to be equal to or less than the calculated maximum transmission power. As a result, when it is necessary to transmit urgently, even if the impedance of the antenna 4 is unknown, the transmitting device 2 can be transmitted immediately without damaging the circuit components in the antenna matching device 3. it can.

Next, a modified embodiment in which the matching process in step 31 of the above embodiment is changed will be described. In the modified embodiment, the extraneous wave power is detected before the matching operation, and the transmission output at the time of the matching operation is determined based on the detected extraneous wave power. Specifically, in step 31 described above, the control unit 11 first monitors the rectified voltage V13, and determines the transmission power during matching operation to be transmitted to the transmitting device 2 based on the rectified voltage V13. In this case, the transmission power during the matching operation is determined as follows. First, the external wave power P
G is approximated by Equation 5 below. PG = (rectified voltage V13 ÷ rectified efficiency) ² ÷ (resistance value of resistor 27) (Equation 5) In this case, the value obtained by dividing the rectified voltage V13 by the rectified efficiency is
It is equal to the high frequency voltage V3 of the external wave applied to both ends of the resistor 27. The coupling refers to the coupling of the current transformer 26 described above. In this case, since the matching between the antenna 4, the antenna matching device 3, and the transmitting device 2 is not perfect, Expression 5 does not accurately represent the extraneous wave power. However, the inventor has found that the extraneous wave power is within a certain range (for example, 1 /
(4 to 4 times), it can be used as a schematic expression.

Next, the control unit 11 determines the transmission power during the matching operation such that the external wave power does not affect the matching operation. In the present embodiment, although not particularly limited, it is determined to be five times the external wave power (more preferably, about ten times). Then, a transmission power control signal that becomes the determined matching operation transmission power is output to the transmission device 2. In addition,
When the extraneous wave power is equal to or higher than a predetermined power (for example, 4 W), the control unit 11 outputs a matching operation stop signal to the transmitting device instead of the transmission power control signal, and the extraneous wave power becomes equal to or lower than the predetermined power. Suspend the alignment process until This is because, when another antenna is arranged adjacent to the antenna 4, a transmission wave (external wave) emitted from the other antenna is induced to the antenna 4 as a considerably large external wave power. The induced extraneous wave is transmitted to the antenna matching device 3
, The standing wave ratio detected by the sensor 12 becomes inaccurate. As a result, the control unit 11 cannot find a normal matching point, and in such a case, the external wave power This is because if the transmission power at the time of the matching operation of five times is output to the transmitting device 2, the antenna matching device 13 may be damaged.

As described above, according to the modified embodiment, it is possible to prevent the antenna matching device 3 from being damaged at the time of the matching operation and to prevent a matching error.

In this embodiment, the antenna matching device 3
Outputs a transmission power control signal to the transmission device 2 and thereby controls the maximum transmission power of the transmission device 2, but is not limited thereto, and outputs data representing the maximum transmission power to the transmission device 2, for example. The maximum transmission power may be displayed on an operation panel or the like of the transmission device, and transmitted to the transmission device 2 at a value equal to or less than the displayed maximum transmission power.

Further, the locations for detecting the high-frequency current and the high-frequency voltage are not limited to the locations described in the present embodiment, but may be any locations in the antenna matching device 3. However, when the imaginary component of the antenna impedance is large, a maximum high-frequency voltage is generally applied to the end of the antenna 4, so that it is preferable to detect the high-frequency voltage at the end of the antenna 4. On the other hand, when the pure resistance of the antenna impedance is small, the maximum high-frequency current generally flows through the antenna 4, so it is preferable to detect the high-frequency current flowing through the antenna 4.

Further, in the present embodiment, an example has been described in which the antenna matching device 3 automatically performs the matching process. However, the present invention is not limited to this, and the present invention can be applied to a case where the matching process is performed manually. .

[0042]

As described above, according to the transmission power control method and the transmission power control apparatus according to the present invention, when the antenna impedance is unknown or when the antenna is damaged and the impedance changes, the antenna matching is performed. During the matching operation between the antenna and the transmitting device by the device, and during the normal transmission of the transmitting device after the matching, a high-frequency signal exceeding the maximum allowable applied voltage or the maximum allowable passing current of the circuit components in the antenna matching device is generated in the antenna matching device. Is transmitted to the transmitting device immediately without damaging the circuit components in the antenna matching device. In addition, since matching is performed with the transmission power during the matching operation based on the extraneous wave power induced in the antenna, damage to the antenna matching device is prevented during the matching operation, and a matching error in the matching operation is prevented. .

[Brief description of the drawings]

FIG. 1 is a block diagram of a communication system according to an embodiment.

FIG. 2 is a flowchart illustrating processing contents of a control unit according to the embodiment.

[Explanation of symbols]

 2 Transmitter 3 Antenna matching device 4 Antenna 11 Control unit 14 Voltage sensor 15 Current sensor 16 First rectifier 17 Second rectifier

──────────────────────────────────────────────────続 き Continuation of front page (56) References JP-A-54-10610 (JP, A) JP-A-5-284047 (JP, A) JP-A-4-372227 (JP, A) JP-A 63-106 176023 (JP, A) Actually open sho 59-7840 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04B 1/04

Claims (4)

(57) [Claims] 1. A transmission power control method for controlling transmission power of a transmission device connected to an antenna via an antenna matching device, wherein the antenna matching device matches the antenna with the transmission device when a matching operation is performed by the antenna matching device. Lowering the transmission power of the transmitting device, and after the matching operation is completed, detecting the antenna voltage applied to the antenna and the antenna current flowing through the antenna in a state where the transmission power is reduced, respectively. , Based on the two detection results,
Calculate the maximum transmission power so as not to exceed the antenna voltage and antenna current allowed by the antenna matching device, and reduce the transmission power of the transmission device after the matching operation to the calculated maximum transmission power or less. Transmission power control method characterized by performing control in the following manner. 2. Before the end of the matching operation, the power of the extraneous wave induced in the antenna is detected, and based on the detected extraneous wave power, the transmitting device transmits during the matching operation at the time of the matching operation. 2. The transmission power control method according to claim 1, wherein power is determined, and the transmission power of the transmitting device is controlled so as to be the determined transmission power during the matching operation during the matching operation. 3. A transmission power control device that is connected to an antenna via an antenna matching device and controls transmission power of a transmission device whose maximum transmission power is regulated by a transmission power control signal, the transmission power control device being applied to the antenna. An antenna voltage detection unit that detects an antenna voltage that is being detected, an antenna current detection unit that detects an antenna current that is flowing through the antenna, and a matching operation performed by the antenna matching device that matches the antenna with the transmitting device. A transmission power control unit configured to reduce the transmission power of the transmission device according to the transmission power control signal, and the antenna voltage detection unit and the antenna current detection unit after the matching operation is completed and the transmission power is reduced. Based on the respective detection results, the antenna voltage allowed by the antenna matching device and A transmission power calculation unit that calculates a maximum transmission power that does not exceed the antenna current, wherein the transmission power control unit calculates the transmission power of the transmission device after the matching operation by the calculated maximum transmission power. A transmission power control device that outputs the transmission power control signal as described below to the transmission device. 4. An external wave power detection unit that detects the power of an external wave induced in the antenna, and based on the detected external wave power, a transmission power during the matching operation of the transmitting device during the matching operation. And a transmission power control unit that determines a transmission power during the matching operation, wherein the transmission power control unit determines the transmission power during the matching operation so that the transmission power of the transmitting device becomes the determined transmission power during the matching operation. The transmission power control device according to claim 3, wherein a signal is output to the transmission device.