JP5958206B2 - Wireless communication apparatus and wireless adjustment method - Google Patents

Description

  The present invention relates to a wireless communication apparatus and a wireless adjustment method.

  Conventionally, a wireless communication device such as a mobile phone is shipped after wireless adjustment is performed at the time of manufacture. Radio adjustment includes transmission adjustment and reception adjustment. In transmission adjustment, arbitrarily set output power is measured by a measuring instrument, and the difference between the set power and actual power is fed back to the wireless communication apparatus as a correction value to adjust the transmission circuit.

  In the reception adjustment, arbitrarily set power is output from the measuring instrument to the wireless communication device, and the wireless communication device identifies input power as RSSI (Received Signal Strength Indicator). Then, the difference between the RSSI and the actual power is fed back to the wireless communication apparatus as a correction value to adjust the receiving circuit.

  As described above, the wireless communication device is shipped after adjusting the transmission circuit so that transmission can be performed with arbitrary transmission power and adjusting the reception circuit so that arbitrary transmission power can be accurately received. In recent years, a technique for adjusting a receiving circuit by returning a signal output from a transmitting circuit to a receiving circuit is known.

JP 09-2322991 A JP 2009-231917 A Japanese Patent Laid-Open No. 06-237229

  However, the above technique has a problem that wireless adjustment cannot be performed accurately. For example, the above technique assumes TDD (Time Division Duplex) that uses the same frequency for transmission and reception, and cannot be applied to FDD (Frequency Division Duplex) that uses different frequencies for transmission and reception. .

  Moreover, even if it can be applied to a wireless communication apparatus using FDD, such a wireless communication apparatus is designed so that the gain of the reception band can be obtained most. For this reason, even if a transmission signal in a band lower than the reception band is fed back to the reception circuit, an RSSI lower than the reception band can be obtained, and radio adjustment cannot be performed accurately.

  The disclosed technique has been made in view of the above, and an object thereof is to provide a wireless communication apparatus and a wireless adjustment method capable of accurately performing wireless adjustment.

  In one aspect, a wireless communication device disclosed in the present application is connected to a transmission circuit and a reception circuit, and includes a shared unit that switches between transmission and reception of wireless communication and shares an antenna. The wireless communication device disclosed in the present application includes a first switching unit that switches an output destination of a transmission signal output from the transmission circuit from the antenna to the reception circuit when adjustment of the reception circuit is executed. The wireless communication device disclosed in the present application includes a second switching unit that switches a reception destination received by the receiving circuit from the shared unit to the first switching unit when adjustment of the receiving circuit is executed. A wireless communication device disclosed in the present application is a value obtained by adding a gain difference between a reception band and a transmission band to a reception power value of a transmission signal received by the reception circuit by switching between the first switching unit and the second switching unit. And an adjustment unit that adjusts the receiving circuit using the correction value determined based on.

  According to one aspect of the wireless communication device and the wireless adjustment method disclosed in the present application, there is an effect that the wireless adjustment can be executed accurately.

FIG. 1 is a configuration diagram of a system that performs adjustment of a receiving circuit according to the first embodiment. FIG. 2 is a diagram for explaining the LNA gain. FIG. 3 is a diagram illustrating adjustment of the receiving circuit according to the first embodiment. FIG. 4 is a flowchart illustrating the flow of adjustment of the receiving circuit according to the first embodiment. FIG. 5 is a configuration diagram of a system that performs adjustment of the transmission circuit according to the second embodiment. FIG. 6 is a diagram illustrating adjustment of the transmission circuit according to the second embodiment. FIG. 7 is a flowchart illustrating a flow of adjustment of the transmission circuit according to the second embodiment.

  Embodiments of a wireless communication apparatus and a wireless adjustment method disclosed in the present application will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

[System Configuration]
In the first embodiment, an example of adjusting a receiving circuit of a mobile phone will be described. FIG. 1 is a configuration diagram of a system that performs adjustment of a receiving circuit according to the first embodiment. As shown in FIG. 1, this system includes a power meter 1, a PC (personal computer) 5, and an FDD mobile phone 10. The connection between the power meter 1 and the mobile phone 10 may be wireless or wired.

  Assume that the mobile phone 10 transmits a transmission signal in a band smaller than the band of the reception signal. In the first embodiment, it is assumed that the transmission circuit in the mobile phone 10 has been adjusted using a known technique or the like.

  The power meter 1 is an inexpensive measuring instrument that measures transmission power transmitted from the mobile phone 10. The PC 5 monitors the transmission power value measured by the power meter 1, the power value when the transmission circuit of the mobile phone 10 transmits a signal, the RSSI value received by the reception circuit of the mobile phone 10, and the like. The PC 5 notifies the mobile phone 10 of the correction value calculated based on the monitoring result.

  The mobile phone 10 includes an antenna 11, a first switch 12, a DUP (Duplexer) 13, a second switch 14, an RF-LSI (Radio Frequency-Large Scale Integration) 15, a BB (Base Band) -LSI 16, and a PA (Power Amplifier). 17.

  The antenna 11 is connected to the first switch 12 and executes transmission signal transmission and reception signal reception. For example, the antenna 11 transmits a transmission signal input from the RF-LSI 15 via the PA 17, the DUP 13, and the first switch 12 to the power meter 1. The antenna 11 outputs the received reception signal to the DUP 13.

  The first switch 12 switches the connection state in order to output a transmission signal to the reception circuit without going through the DUP 13 when adjusting the reception circuit. Specifically, the first switch 12 is connected to the DUP 13 at the end point P1, connected to the antenna 11 at the end point P2, and connected to the second switch 14 at the end point P3. And the 1st switch 12 connects P1 and P2 at the time of transmission circuit adjustment, and produces | generates the path | route which outputs a transmission signal to the antenna 11. FIG. The first switch 12 connects P1 and P3 when adjusting the receiving circuit, and generates a path through which the transmission signal is fed back to the receiving circuit.

  The DUP 13 is connected to each of the first switch 12, the second switch 14, and the PA 17, and switches the transmission / reception of wireless communication to share the antenna. A circuit on the PA 17 side connected to the DUP 13 functions as a transmitter (Tx: Transmit eXchange), and a circuit on the second switch 14 side connected to the DUP 13 functions as a receiver (Rx: Received eXchange). The DUP 13 has a function similar to that of the duplexer included in the general mobile phone 10, and thus detailed description thereof is omitted.

  The second switch 14 switches the reception destination received by the reception circuit from the DUP 13 to the first switch 12 when adjustment of the reception circuit is executed. Specifically, the second switch 14 is connected to the DUP 13 at the end point P1, connected to the RF-LSI 15 at the end point P2, and connected to the first switch 12 at the end point P3. The second switch 14 connects P1 and P2 during transmission circuit adjustment, and generates a path through which the received signal is output from the DPU 13. Further, the second switch 14 connects P2 and P3 when adjusting the receiving circuit, and generates a path through which the transmission signal is fed back to the receiving circuit.

  The RF-LSI 15 includes an Rx oscillator 15a, a variable LNA (Low Noise Amplifier) 15b, a mixer 15c, a Tx oscillator 15d, a mixer 15e, and a variable amplifier 15f, and generates a transmission signal and D / A (digital / analog) of a reception signal. ) A circuit that performs conversion and the like. The RF-LSI 15 executes the same processing as the RF circuit included in a general wireless communication device such as a mobile phone.

  The Rx oscillator 15a is connected to the mixer 15c and outputs the same frequency as the transmission frequency or the reception frequency input to the RF-LSI 15 to the mixer 15c. The variable LNA 15b is connected to the second switch 14 and the mixer 15c, and increases or decreases the gain depending on the strength of the signal input from the second switch 14. The mixer 15c is connected to the Rx oscillator 15a, the variable LNA 15b, and the BB-LSI 16, mixes the signal input from the variable LNA 15b and the output from the Rx oscillator 15a, converts the mixed signal into a baseband signal, and converts it to the BB-LSI 16 Output to.

  Here, the gain of the variable LNA will be described. FIG. 2 is a diagram for explaining the LNA gain. FIG. 2 is a diagram in which the horizontal axis represents frequency (Freq.) And the vertical axis represents gain (Gain). As shown in FIG. 2, the variable LNA 15b in the RF-LSI 15 is designed so that the gain of the reception band can be obtained most, and the gain of the transmission band is “αdB” lower than the reception band. For this reason, even if the transmission signal (f1) is input to the reception side, an RSSI lower than the reception band can be obtained. Therefore, the correction value of “αdB” is stored in advance in the RF-LSI 15 or the BB-LSI 16 as an initial data value, and the correction value is added and adjusted when adjusting the receiving circuit using the transmission signal. I do. If the transmission band is widened so as to have the same gain as the reception band, NF deteriorates and the sensitivity of the apparatus deteriorates, which is not realistic.

  Returning to FIG. 1, the Tx oscillator 15d is connected to the mixer 15e, and connects the transmission frequency to the mixer 15e. The mixer 15e is connected to the Tx oscillator 15d and the BB-LSI 16, mixes the baseband signal input from the BB-LSI 16 and the output from the Tx oscillator 15d, converts it to a transmission signal, and supplies it to the variable amplifier 15f. Output. The variable amplifier 15f increases or decreases the gain, and adjusts the output of the transmission signal output from the mixer 15e.

  The BB-LSI 16 is a circuit that is connected to the mixer 15c and the mixer 15e and executes baseband processing. For example, the BB-LSI 16 performs demodulation processing, error correction, and the like on the baseband signal input from the mixer 15c. The BB-LSI 16 outputs a baseband signal to the mixer 15e. The BB-LSI 16 executes the same processing as that of a baseband circuit included in a general wireless communication device such as a mobile phone.

  Further, the BB-LSI 16 adjusts the transmission circuit and the reception circuit based on the correction value notified from the PC 5. An example of the transmission circuit is a circuit from the BB-LSI 16 to the mixer 15e, the variable amplifier 15f, the PA 17, and the DUP 13. An example of the receiving circuit is a circuit from the DUP 13 to the second switch 14, the variable LNA 15 b, the mixer 15 c, and the BB-LSI 16. Further, the BB-LSI 16 performs software adjustment such as changing the setting value of each circuit as adjustment of the transmission circuit and the reception circuit.

  The PA 17 is connected to the variable amplifier 15f, and amplifies the transmission signal output from the variable amplifier 15f so as to have a predetermined magnitude.

[Reception circuit adjustment example]
FIG. 3 is a diagram illustrating adjustment of the receiving circuit according to the first embodiment. The system configuration shown in FIG. 3 is the same as that shown in FIG. In the first embodiment, it is assumed that the transmission circuit in the mobile phone 10 has been adjusted.

  Specifically, the mobile phone 10 connects P1-P2 of the first switch 12 and connects P1-P2 of the second switch 14. As a result, the transmission signal is output from the antenna 11 to the power meter 1 via the DUP 13 and the first switch 12.

  In such a state, the power meter 1 measures the transmission power value of the transmission signal output from the RF-LSI 15 of the mobile phone 10 via the PA 17, DUP 13, first switch 12, and antenna 11. On the other hand, the PC 5 monitors the transmission power value of the transmission signal measured by the power meter 1 and the transmission power value at the time of output from the antenna 11, and notifies the mobile phone 10 of the difference. The BB-LSI 16 of the mobile phone 10 performs transmission adjustment based on the difference notified from the PC 5. For example, the BB-LSI 16 performs adjustment such as setting values of each circuit so that transmission can be performed with desired power.

  In this way, when the adjustment of the transmission circuit is completed, the mobile phone 10 connects P1-P3 of the first switch 12 and connects P3-P2 of the second switch 14. As a result, the transmission signal is not output from the antenna 11 via the DUP 13 and the first switch 12 but is output to the second switch 14. That is, the transmission signal bypasses the DUP 13 and is fed back to the receiving circuit.

  In such a state, the PC 5 inputs the transmission signal output from the RF-LSI 15 of the mobile phone 10 via the PA 17, DUP 13, and the first switch 12 to the reception circuit via the second switch 14 and outputs the RSSI. Monitor. Then, the PC 5 adds the gain difference shown in FIG. 2 to the monitored RSSI. Thereafter, the PC 5 determines whether or not the value obtained by adding the gain difference satisfies the desired RSSI. Then, the PC 5 calculates a correction value so as to satisfy the desired RSSI, and notifies the mobile phone 10 of the correction value. The BB-LSI 16 of the mobile phone 10 performs reception adjustment based on the correction value notified from the PC 5.

Here, a correction example of the receiving circuit will be described. For example, a transmission signal is output from the adjusted transmission circuit of the mobile phone 10 as “0 dBm”. The transmission signal is input to the reception circuit via the first switch 12 and the second switch 14. Here, since “0 dBm” is input, the PC 5 confirms whether the RSSI is between “−0.2 dBm” that is RSSI _min and “0.2 dBm” that is RSSI _max . Here, it is assumed that RSSI is “−1 dBm”. Then, the PC 5 determines that the correction value is “1 dBm” because “1 dBm” is less than the RSSI _min , and the BB-LSI 16 adds the correction value “1 dBm”. After that, when the RSSI is confirmed again, it is monitored to be “0.1 dBm”, and is within the RSSI _min “−0.2 dBm” to RSSI _max “0.2 dBm”, so that the reception adjustment is completed.

[Process flow]
FIG. 4 is a flowchart illustrating the flow of adjustment of the receiving circuit according to the first embodiment. As shown in FIG. 4, when the transmission adjustment of the mobile phone 10 is completed (S101), the system shown in FIG. 1 starts the reception adjustment of the mobile phone 10 (S102).

  Subsequently, the cellular phone 10 switches the connection of the first switch 12 to the receiving circuit side, that is, P1-P3 (S103). Then, the mobile phone 10 switches the connection of the second switch 14 to the first switch 12 side, that is, P2-P3 (S104).

  Then, the mobile phone 10 starts transmission of a transmission signal (S105), and the PC 5 monitors RSSI when the transmission signal is received by the reception circuit (S106). Subsequently, the PC 5 adds the gain difference stored in the mobile phone 10 to the monitored RSSI (S107).

After that, the PC 5 determines whether the RSSI (monitor value) obtained by adding the gain difference is within a predetermined RSSI _min and RSSI _MAX (S108). Here, RSSI _min is a predetermined minimum allowable RSSI value, and RSSI _MAX is a predetermined maximum allowable RSSI value.

When the PC5 determines that the RSSI obtained by adding the gain difference does not fit between the RSSI _min and the RSSI _MAX (S108: No), the PC5 calculates the correction value so as to fit, and the BB-LSI 16 is calculated. The receiving circuit is adjusted using the correction value (S109). For example, PC 5, if RSSI obtained by adding the gain difference is smaller than the _{RSSI min,} calculates a correction value equal to or greater than the _{RSSI min,} RSSI obtained by adding the gain difference is smaller than the _{RSSI max,} the correction value that is less _{RSSI max} calculate.

Thereafter, when the BB-LSI 16 adjusts the reception circuit using the calculated correction value, the reception adjustment is completed (S110). In addition, when the PC 5 determines that the RSSI obtained by adding the gain difference falls within the RSSI _min and the RSSI _MAX (S108: Yes), the reception adjustment is completed.

  As described above, the mobile phone 10 according to the first embodiment includes a switch that switches between the normal route and the adjustment route, and the function of correcting the gain difference between the transmission bandwidth and the reception bandwidth of the LNA is used for the mobile phone 10 that is adjusted for transmission. Use the radio (transmitting side) instead of the measuring instrument. As a result, it is possible to perform radio adjustment on the receiving side using the own device. That is, by using the radio device (transmission side) of the own device adjusted for transmission instead of the measuring device, it is possible to perform radio adjustment on the reception side of the own device. As a result, wireless adjustment can be performed using only an inexpensive measuring device capable of performing only reception measurement without using an expensive measuring device capable of performing both transmission measurement and reception measurement as in the prior art.

  Further, the gain difference between the transmission band and the reception band can be added to the RSSI detected by the reception circuit, and the reception circuit can be adjusted using this value, so that the radio adjustment can be performed accurately. it can. Further, even in a mobile phone to which FDD that uses different frequencies for transmission and reception is applied, wireless adjustment can be performed accurately.

  In the first embodiment, the example in which the reception circuit is adjusted has been described. However, even when the transmission circuit is adjusted, the wireless adjustment can be accurately performed. In the second embodiment, an example in which the transmission circuit is adjusted will be described.

[System Configuration]
FIG. 5 is a configuration diagram of a system that performs adjustment of the transmission circuit according to the second embodiment. As shown in FIG. 5, this system includes a signal generator 6, a PC 5, and an FDD mobile phone 10. The connection between the signal generator 6 and the mobile phone 10 may be wireless or wired. In the second embodiment, it is assumed that the receiving circuit in the mobile phone 10 has been adjusted using a known technique or the like.

  The signal generator 6 is an inexpensive measuring device that transmits a transmission signal having a designated power to the mobile phone 10. The PC 5 monitors the power value when the transmitting circuit of the mobile phone 10 transmits a signal, the power value of the signal generated by the signal generator 6, the RSSI value received by the receiving circuit, and the like. Then, the PC 5 notifies the mobile phone 10 of the correction value calculated based on the monitoring result.

  The configuration of the mobile phone 10 is the same as that of the first embodiment, but the timing at which the first switch 12 and the second switch 14 switch the connection is different. Specifically, the first switch 12 switches the connection state in order to output a transmission signal to the reception circuit without going through the DUP 13 when adjusting the transmission circuit. For example, the first switch 12 connects P <b> 1 and P <b> 2 during reception circuit adjustment, and generates a path for outputting a transmission signal to the antenna 11. The first switch 12 connects P1 and P3 when adjusting the transmission circuit, and generates a path through which the transmission signal is fed back to the reception circuit.

  The second switch 14 switches the reception destination received by the reception circuit from the DUP 13 to the first switch 12 when adjustment of the transmission circuit is executed. For example, the second switch 14 connects P <b> 1 and P <b> 2 during reception circuit adjustment, and generates a path through which the reception signal is output from the DPU 13. In addition, the second switch 14 connects P2 and P3 during transmission circuit adjustment, and generates a path through which the transmission signal is fed back to the reception circuit.

[Example of transmitter adjustment]
FIG. 6 is a diagram illustrating adjustment of the transmission circuit according to the second embodiment. The system configuration shown in FIG. 6 is the same as that shown in FIG. In the second embodiment, it is assumed that the receiving circuit in the mobile phone 10 has been adjusted.

  Specifically, the mobile phone 10 connects P1-P2 of the first switch 12 and connects P1-P2 of the second switch 14. As a result, the transmission signal transmitted from the signal generator 6 is input to the reception circuit via the antenna 11, the first switch 12, and the DUP 13.

  In such a state, the PC 5 measures the RSSI of the transmission signal received by the receiving circuit of the mobile phone 10. The PC 5 compares the power value of the transmission signal generated by the signal generator 6 with the RSSI measured by the receiving circuit, calculates a difference, and notifies the mobile phone 10 of the difference. The BB-LSI 16 of the mobile phone 10 performs reception adjustment based on the difference notified from the PC 5. For example, the BB-LSI 16 performs adjustment such as a set value of each circuit so that reception can be performed with desired power.

  Thus, when the adjustment of the receiving circuit is completed, the mobile phone 10 connects P1-P3 of the first switch 12 and connects P3-P2 of the second switch 14. As a result, the transmission signal transmitted from the transmission circuit of the mobile phone 10 is not output from the antenna 11 via the DUP 13 and the first switch 12 but is output to the second switch 14. That is, the transmission signal bypasses the DUP 13 and is fed back to the receiving circuit.

  In such a state, the PC 5 inputs the transmission signal output from the RF-LSI 15 of the mobile phone 10 via the PA 17, DUP 13, and the first switch 12 to the reception circuit via the second switch 14 and outputs the RSSI. Monitor. Then, the PC 5 adds the gain difference shown in FIG. 2 to the monitored RSSI. Thereafter, the PC 5 determines whether or not the value obtained by adding the gain difference satisfies the desired RSSI. Then, the PC 5 calculates a correction value so as to satisfy the desired RSSI, and notifies the mobile phone 10 of the correction value. The BB-LSI 16 of the mobile phone 10 performs transmission adjustment based on the correction value notified from the PC 5.

[Process flow]
FIG. 7 is a flowchart illustrating a flow of adjustment of the transmission circuit according to the second embodiment. As shown in FIG. 7, when the reception adjustment of the mobile phone 10 is completed (S201), the system shown in FIG. 5 starts the transmission adjustment of the mobile phone 10 (S202).

  Subsequently, the cellular phone 10 switches the connection of the first switch 12 to the receiving circuit side, that is, P2-P3 (S203). Then, the mobile phone 10 switches the connection of the second switch 14 to the first switch 12 side, that is, P2-P3 (S204).

  Then, the cellular phone 10 starts transmission of a transmission signal (S205), and the PC 5 monitors RSSI when the transmission signal is received by the reception circuit (S206). Subsequently, the PC 5 adds the gain difference stored in the mobile phone 10 to the monitored RSSI (S207).

After that, the PC 5 determines whether the RSSI obtained by adding the gain difference is within the predetermined RSSI _min and RSSI _MAX (S208). When the PC5 determines that the RSSI obtained by adding the gain difference does not fit between RSSI _min and RSSI _MAX (S208: No), the PC5 calculates the correction value so that it fits, and the BB-LSI 16 is calculated. The transmission circuit is adjusted using the correction value (S209). Thereafter, when the BB-LSI 16 adjusts the transmission circuit using the calculated correction value, the transmission adjustment is completed (S210). Further, when the PC 5 determines that the RSSI obtained by adding the gain difference falls within the RSSI _min and the RSSI _MAX (S208: Yes), the transmission adjustment is completed.

  As described above, the mobile phone 10 according to the second embodiment includes a switch that switches between the normal route and the adjustment route, and the function of correcting the gain difference between the transmission bandwidth and the reception bandwidth of the LNA is used for the mobile phone 10 that has received reception adjustment. Use the radio (reception side) instead of the measuring instrument. As a result, it is possible to perform wireless adjustment on the transmission side using the own device. In other words, by using the reception-adjusted radio (reception side) instead of the measuring device, radio adjustment on the transmission side of the own apparatus can be performed. As a result, wireless adjustment can be performed using only an inexpensive measuring instrument capable of performing only transmission measurement without using an expensive measuring instrument capable of performing both transmission measurement and reception measurement as in the prior art.

  Further, the gain difference between the transmission band and the reception band can be added to the RSSI detected by the reception circuit, and the transmission circuit can be adjusted using this value, so that the radio adjustment can be accurately performed. it can. Further, even in a mobile phone to which FDD that uses different frequencies for transmission and reception is applied, wireless adjustment can be performed accurately.

  Although the embodiments of the present invention have been described so far, the present invention may be implemented in various different forms other than the embodiments described above. Therefore, different embodiments will be described below.

(Target device)
In the first and second embodiments, the mobile phone wireless adjustment has been described as an example. However, the present invention is not limited to this. For example, a wireless communication device having a wireless function, such as a smartphone, can execute wireless adjustment by the same method. In addition, the circuit configuration of the mobile phone described in the first embodiment and the second embodiment is an example, and may have a circuit or heartware other than those illustrated.

(Add gain difference)
In the first and second embodiments, an example has been described in which the PC 5 acquires a gain difference stored in advance from the BB-LSI 16 of the mobile phone 10 and adds the gain difference to the monitored RSSI. However, the present invention is not limited to this. is not. For example, the PC 5 determines whether or not the monitored RSSI is a numerical value within a predetermined range, and calculates a correction value that falls within the predetermined range. The BB-LSI 16 can also calculate a difference between the notified correction value and a gain difference stored in advance, and perform wireless adjustment using the calculated difference.

(system)
In addition, among the processes described in the present embodiment, all or a part of the processes described as being automatically performed can be manually performed. Alternatively, all or part of the processing described as being performed manually can be automatically performed by a known method. In addition, the processing procedure, control procedure, specific name, and information including various data and parameters shown in the above-described document and drawings can be arbitrarily changed unless otherwise specified.

  Further, each component of each illustrated apparatus is functionally conceptual, and does not necessarily need to be physically configured as illustrated. That is, the specific form of distribution and integration of each device is not limited to the illustrated one. That is, all or a part of them can be configured to be functionally or physically distributed / integrated in arbitrary units according to various loads or usage conditions. Further, all or any part of each processing function performed in each device may be realized by a CPU and a program analyzed and executed by the CPU, or may be realized as hardware by wired logic.

1 Power meter 5 PC
6 Signal Generator 10 Mobile Phone 11 Antenna 12 First Switch 13 DUP
14 Second switch 15 RF-LSI
15a Rx oscillator 15b Variable LNA
15c mixer 15d Tx oscillator 15e mixer 15f variable amplifier 16 BB-LSI
17 PA

Claims (6)

A shared unit that is connected to the transmission circuit and the reception circuit, switches between transmission and reception of wireless communication, and shares an antenna;
Before adjusting the receiving circuit, an output destination of a transmission signal output from the transmission circuit is connected to the antenna, a first transmission power value of a transmission signal output from the transmission circuit, and the antenna When adjusting the transmission circuit using the difference from the second transmission power value of the transmission signal to be output and adjusting the reception circuit, the output destination of the adjusted transmission circuit is the antenna. A first switching section for switching from the receiving circuit to the receiving circuit;
When you perform the adjustment of the reception circuit, a second switching section for switching the destination of the receiving circuit receives the first switching unit from the common unit,
A correction value determined based on a value obtained by adding a gain difference between a reception band and a transmission band to a reception power value of a transmission signal received by the reception circuit by switching between the first switching unit and the second switching unit. And an adjustment unit that adjusts the receiving circuit.   The adjustment unit is a correction value determined so that a value obtained by adding the gain difference to the received power value is a value between a predetermined minimum power value and a maximum power value according to the power value of the transmission signal. The radio communication apparatus according to claim 1, wherein the receiving circuit is adjusted using a radio frequency (V). A shared unit that is connected to the transmission circuit and the reception circuit, switches between transmission and reception of wireless communication, and shares an antenna;
Before adjusting the transmission circuit, the reception circuit and the antenna are connected, and the first power value of the transmission signal input to the reception circuit and the second of the transmission signal received by the reception circuit using the difference between the power value, the adjusted reception circuit, if you run the adjustment of the transmission circuit, adjusted the receiving the output destination of the transmission signal output from the transmission circuit from the antenna A first switching unit for switching to a circuit;
When you perform the adjustment of the transmission circuit, a second switching section for switching the destination of the adjusted the receiving circuit receives the first switching unit from the common unit,
Determined based on a value obtained by adding a gain difference between the reception band and the transmission band to the reception power value of the transmission signal received by the reception circuit adjusted by the switching by the first switching unit and the second switching unit A wireless communication apparatus comprising: an adjustment unit that adjusts the transmission circuit using a correction value.   The adjustment unit is a correction value determined so that a value obtained by adding the gain difference to the received power value is a value between a predetermined minimum power value and a maximum power value according to the power value of the transmission signal. The radio communication apparatus according to claim 3, wherein the transmission circuit is adjusted using a radio frequency. A wireless communication device having a transmission circuit and a reception circuit ,
Before adjusting the receiving circuit, using the difference between the first transmission power value of the transmission signal output from the transmission circuit and the second transmission power value of the transmission signal output from the antenna, Adjust the transmission circuit,
When adjusting the reception circuit unadjusted, switches the output destination of the transmission signal to the reception circuit, is fed back the transmission signal output from the adjusted the transmission circuit to the reception circuit,
Measure the power value of the received signal in the receiving circuit that received the feedback transmission signal,
Radio adjustment characterized by performing a process of adjusting the reception circuit using a correction value determined based on a value obtained by adding a gain difference between a reception band and a transmission band to a measured power value of a reception signal Method. A wireless communication device having a transmission circuit and a reception circuit ,
Before adjusting the transmission circuit, the reception circuit and the antenna are connected, and the first power value of the transmission signal input to the reception circuit and the second of the transmission signal received by the reception circuit Using the difference with the power value, adjust the receiving circuit,
When adjusting the transmission circuit unadjusted, switches the output destination of the transmission signal to an adjusted the receiving circuit, is fed back a transmission signal output from the transmission circuit to an adjusted said receiving circuit,
Measure the power value of the received signal in the adjusted receiving circuit that has received the feedback transmitted signal,
Radio adjustment characterized by executing a process of adjusting the transmission circuit using a correction value determined based on a value obtained by adding a gain difference between a reception band and a transmission band to a measured power value of a reception signal Method.

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