JP2013258476A - Radio device, impedance control device, impedance control method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a variation in impedance at gain switching of a switchable gain amplifier, and reduce power consumption in impedance matching.SOLUTION: A control section 110 controls the impedance of matching circuits 140 and 160 on the basis of the gain of a power amplifier 150 and the setting of a TXAGC amplifier 131. The control section 110 can thus perform finer control depending on a signal level from the TXAGC amplifier 131 as well as the gain of the power amplifier 150. Especially, the control section 110 can reduce a variation in impedance at gain switching of the power amplifier 150 and reduce power consumption in impedance matching.

Description

  The present invention relates to a wireless device, an impedance control device, an impedance control method, and a program.

  A technique for switching the gain of an amplifier according to a transmission output level when a transmission signal of a mobile phone is amplified is known. Specifically, a power amplifier that changes a transmission output level of a mobile phone in response to a power control signal from a base station includes a plurality of amplifiers having different gains. When the transmission output level required by the power control signal exceeds a certain range, the transmission signal is amplified by switching to an amplifier having a different gain.

  Here, by switching the gain of the amplifier, the input impedance and output impedance of the amplifier vary for each gain. The fluctuation of the input impedance or output impedance affects the transmission output level, which may adversely affect the control of the transmission output level. Specifically, due to fluctuations in the transmission output level at the time of gain switching, a location where the transmission output level of the mobile phone varies greatly with respect to the command value of the power control signal from the base station (so-called discontinuous location) occurs. Can be considered. When such a location occurs, feedback control in which the base station generates and transmits a power control signal according to the signal level from the mobile phone may not converge.

On the other hand, the receiving circuit described in Patent Document 1 includes a matching circuit, an LNA (Low Noise Amplifier) capable of switching gains in two stages, a programmable gain amplifier capable of continuous gain switching, and an amplifier. The gain of the amplifier is set so that the output signal becomes a prescribed level. When the received electric field strength is less than or equal to the threshold value, the LNA is operated at the high gain, and when the received electric field strength exceeds the threshold value, the amplifier is operated at the low gain. A gain control unit and a matching circuit control unit that switches the matching constant of the matching circuit so that the input impedance of the LNA when operating at a low gain matches the input impedance of the LNA when operating at a high gain With.
Also in the transmission circuit, it is conceivable that the matching constant of the matching circuit is switched in accordance with the gain switching of the amplifier to reduce the variation in impedance at the time of the gain switching, thereby reducing the variation in the transmission output level.

JP 2010-87954 A

  When reducing fluctuations in impedance at the time of amplifier gain switching, if power consumption in impedance matching can be reduced, power can be effectively utilized. For example, if power consumption in a mobile phone can be reduced, the battery can run out of the mobile phone and the usable time can be extended.

  An object of the present invention is to provide a wireless device, an impedance control device, an impedance control method, and a program that can solve the above-described problems.

  The present invention has been made to solve the above-described problem. A wireless device according to an aspect of the present invention includes an amplifier having a variable gain, a power amplifier that switches a gain according to a required output level, and the power. A matching circuit that performs impedance matching of an amplifier, and a control unit that controls the impedance of the matching circuit based on a gain of the power amplifier and a setting of the amplifier that can change the gain.

  The impedance control device according to one aspect of the present invention performs impedance matching of the power amplifier based on the gain of the power amplifier that amplifies the output of the amplifier with variable gain and the setting of the amplifier with variable gain. The impedance of the matching circuit is controlled.

  An impedance control method according to an aspect of the present invention includes an amplifier having a variable gain, a power amplifier that switches gain according to a required output level, and a matching circuit that performs impedance matching of the power amplifier. An impedance control method for a wireless device, comprising a control step of controlling the impedance of the matching circuit based on a gain of the power amplifier and a setting of an amplifier capable of changing the gain.

  According to another aspect of the present invention, there is provided a program comprising: an amplifier having a variable gain; a power amplifier that switches the gain according to a required output level; and a matching circuit that performs impedance matching of the power amplifier. Is a program for causing a computer that controls the impedance of the power amplifier to execute a control step of controlling the impedance of the matching circuit based on the gain of the power amplifier and the setting of the amplifier whose gain is variable.

  According to the present invention, it is possible to reduce impedance variation when switching the gain of an amplifier and to reduce power consumption in impedance matching.

It is a schematic block diagram which shows the function structure of the radio | wireless apparatus in one Embodiment of this invention. 4 is an explanatory diagram illustrating a relationship between a power control signal from a base station device and a transmission output level of a wireless device in the embodiment. FIG. It is a schematic block diagram which shows the circuit structure of the matching circuit in the embodiment. It is explanatory drawing which shows the example of the point corresponding | compatible information which the memory | storage part in the same embodiment memorize | stores. It is a Smith chart which shows the example of the impedance matching which the matching circuit in the embodiment performs. It is explanatory drawing which shows the example of the corresponding circuit information which the memory | storage part in the same embodiment memorize | stores. 4 is a flowchart illustrating a procedure of processing in which a wireless device performs impedance matching in the embodiment. It is a schematic block diagram which shows the minimum structure of this invention in the radio | wireless apparatus of the embodiment.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic block diagram showing a functional configuration of a wireless device according to an embodiment of the present invention. In the figure, a wireless device 100 includes a control unit 110, a storage unit 120, a transmission unit 130, matching circuits 140 and 160, and a power amplifier 150. The transmission unit 130 includes a TXAGC amplifier (automatic gain control amplifier for transmission) 131.

The wireless device 100 is used as a wireless unit of a mobile phone that performs communication using, for example, a W-CDMA (Wideband Code Division Multiple Access) method, and corresponds to a power control signal (Transmit Power Control; TPC) from a base station device. Wireless transmission is performed at the transmission output level (transmission power).
The transmission unit 130 modulates and amplifies a transmission signal given as a digital signal.
The TXAGC amplifier 131 is a variable gain amplifier, and amplifies the transmission signal converted to the carrier frequency with the gain set by the radio apparatus 100.

The power amplifier 150 amplifies the transmission signal from the transmission unit 130. At that time, the power amplifier 150 switches the gain according to the output level required by the power control signal from the base station apparatus.
FIG. 2 is an explanatory diagram showing the relationship between the power control signal from the base station apparatus and the transmission output level of the radio apparatus 100. Here, the power amplifier 150 has a low gain (denoted as “LOW” or “L”), medium (denoted as “MID or“ M ”), or high (denoted as“ HIGH ”or“ H ”). The power amplifier 150 includes three amplifiers, and the power amplifier 150 is used by switching between these amplifiers, thereby switching the gain of the power amplifier 150 in three stages of low, medium, and high to amplify the transmission signal. 2 indicate the relationship between the power control signal and the transmission output level when the power amplifier 150 amplifies the signal at low gain, medium gain, and high gain, respectively.

Each of Point_L1 to Point_H3 in FIG. 2 indicates a point to be described later with reference to FIGS. 4 and 5.
The application range of the present invention is not limited to the case where the power amplifier 150 has three gain switching levels. The gain switching level of the power amplifier 150 may be two, or may be four or more.

Matching circuits 140 and 160 perform impedance matching of power amplifier 150.
Here, when the power amplifier 150 switches the amplifier, the impedance of the power amplifier 150 varies. If the fluctuation in impedance lowers the transmission output level of the wireless device 100, the continuity between the power control signal and the transmission output level as shown in FIG. 2 cannot be obtained. That is, there is a location where the transmission output level of the wireless device 100 varies greatly with respect to the transmission output level requested by the power control signal. Then, when the base station apparatus performs feedback control of the transmission output level of the radio apparatus 100, the feedback control may not converge.

  Therefore, the matching circuit 140 matches the input impedance of the power amplifier 150 when the power amplifier 150 switches the gain, and particularly reduces the fluctuation of the input impedance near the transmission output level at which the power amplifier 150 switches the gain. The matching circuit 160 matches the output impedance of the power amplifier 150 when the power amplifier 150 switches the gain, and particularly reduces fluctuations in the output impedance near the transmission output level at which the power amplifier 150 switches the gain. Thereby, the radio | wireless apparatus 100 can acquire the continuity of a power control signal and a transmission output level. That is, fluctuations in the transmission output level of radio apparatus 100 with respect to the transmission output level requested by the power control signal can be reduced.

FIG. 3 is a schematic configuration diagram showing a circuit configuration of the matching circuit 140. In the figure, the matching circuit 140 includes circuits c _{1 to} c _n (n is a positive integer) having different impedances. The matching circuit 140 changes the impedance of the matching circuit 140 itself by matching the input impedance of the power amplifier 150 by switching the circuits c _{1 to} c _n based on the matching control signal g 13 from the control unit 110.

  Like the matching circuit 140, the matching circuit 160 also includes n circuits having different impedances. The matching circuit 160 also switches the circuit based on the matching control signal g13 from the control unit 110, thereby changing the impedance of the matching circuit 160 itself and matching the output impedance of the power amplifier 150. Note that the impedance of each circuit may be different between the matching circuit 140 and the matching circuit 160.

The storage unit 120 stores point correspondence information that is information in which the gain of the power amplifier 150 and the setting of the TXAGC amplifier 131 are associated with points.
FIG. 4 is an explanatory diagram illustrating an example of the point correspondence information stored in the storage unit 120. The point correspondence information indicates the correspondence between the setting of the TXAGC amplifier 131 and the gain of the power amplifier 150 and the point.

  The point here is information indicating the position of the output level of the power amplifier 150 within the range of the output level at a certain gain. For example, in FIG. 2, Point_L1 indicates a position near the lower end of the output level within the range of the output level indicated by the line L11 when the gain of the power amplifier 150 is low. Point_L3 indicates a position near the upper end of the output level in the output level range indicated by the line L11 when the gain of the power amplifier 150 is low. Point_L2 indicates a position other than the vicinity of the upper end and the lower end of the output level within the output level range indicated by the line L11 when the gain of the power amplifier 150 is low. Similarly, Point_M1, Point_M3, and Point_M2 are other than the position near the lower end of the output level, the position near the upper end, the position near the upper end, and the vicinity of the lower end within the range of the output level indicated by the line L12 in the gain of the power amplifier 150, respectively. Indicates the position. Point_H1, Point_H3, and Point_H2 are positions near the lower end of the output level, near the upper end, near the upper end, and near the lower end, respectively, within the range of the output level indicated by the line L13 at the high gain of the power amplifier 150. Indicates the position.

  “LOW”, “MID”, and “HIGH” illustrated in FIG. 4 indicate the gain of the power amplifier 150, and numerical values 10 to 70 indicate setting values for the TXAGC amplifier 131. Further, “Point_ * 1”, “Point_ * 2”, and “Point_ * 3” indicate the large / medium / small classification of the gain of the TXAGC amplifier 131 for each gain of the power amplifier 150.

Here, the setting value for the TXAGC amplifier 131 indicates a larger gain as the value increases. For example, when the gain of the power amplifier 150 is “LOW”, the setting value “10” indicates the smallest gain, and the setting value “50” indicates the largest gain.
Among these setting values, the setting value “10” having the smallest gain is classified as “Point_ * 1”. Further, the setting value “50” having the largest gain is classified as “Point_ * 3”. The other set values “20” to “40” are classified as “Point_ * 2”.

  Similarly, when the gain of the power amplifier 150 is “MID”, the setting value “20” having the smallest gain is classified as “Point_ * 1”. Further, the set value “60” having the largest gain is classified as “Point_ * 3”. Further, the other set values “30” to “50” are classified as “Point_ * 2”. Further, when the gain of the power amplifier 150 is “HIGH”, the setting value “30” having the smallest gain is classified as “Point_ * 1”. Further, the setting value “70” having the largest gain is classified as “Point_ * 3”. The other set values “40” to “60” are classified as “Point_ * 2”.

  Points are determined by the combination of the classification of “Point_ * 1”, “Point_ * 2”, and “Point_ * 3” and the gain of the power amplifier 150. For example, in the case of “Point_ * 1” and the gain “LOW” (“L”) of the power amplifier 150, the point “Point_L1” is determined. Further, in the case of “Point_ * 3” and the gain “MID” (“M”) of the power amplifier 150, the point “Point_M3” is determined.

Here, the relationship between the points is as shown in FIG. In particular, Point_L3 corresponding to the maximum setting of the gain of the TXAGC amplifier 131 when the gain of the power amplifier 150 is low and Point_M1 corresponding to the minimum setting of the gain of the TXAGC amplifier 131 during the gain of the power amplifier 150 are close at the transmission output level. doing. By reducing the difference between the impedance of the power amplifier 150 at Point_L3 and the impedance of the power amplifier 150 at Point_M1, it is possible to reduce the influence of the impedance difference on the transmission output level. By reducing the influence of the impedance difference (and hence the influence of the efficiency difference of the power amplifier 150), it becomes easy to obtain continuity between the power control signal and the transmission output level as shown in FIG.
Similarly, by reducing the difference between the impedance of the power amplifier 150 at Point_M3 and the impedance of the power amplifier 150 at Point_H1, continuity between the power control signal and the transmission output level can be easily obtained.

  Therefore, the matching circuits 140 and 160 perform impedance matching that reduces the difference in impedance of the power amplifier 150 between Point_L3 and Point_M1 and the difference in impedance of the power amplifier 150 between Point_M3 and Point_H1 under the control of the control unit 110. Do.

  FIG. 5 is a Smith chart illustrating an example of impedance matching performed by the matching circuit 140. In the figure, a point P111 indicates the input impedance of the power amplifier 150 at Point_L3 when the matching circuit 140 does not perform impedance matching. A point P112 indicates the input impedance of the power amplifier 150 at Point_L3 when the matching circuit 140 performs impedance matching.

  A point P121 indicates the input impedance of the power amplifier 150 at Point_M1 when the matching circuit 140 does not perform impedance matching. A point P122 indicates the input impedance of the power amplifier 150 at Point_M1 when the matching circuit 140 performs impedance matching. The matching circuit 140 performs impedance matching that brings the input impedance value of the power amplifier 150 close to a predetermined value (50 ohms (Ω) in the example of FIG. 5) in both Point_L3 and Point_M1, thereby reducing the impedance difference. I am letting.

Similarly, the matching circuit 140 performs impedance matching that brings the input impedance value of the power amplifier 150 close to a predetermined value in both Point_M3 and Point_H1, thereby reducing the difference in impedance. It should be noted that the predetermined value at Point_L3 and Point_M1 and the predetermined value at Point_M3 and Point_H1 may be the same value or different values.
The matching circuit 160 also performs impedance matching that brings the output impedance value of the power amplifier 150 close to a predetermined value at the Point_L3, the Point_M1, and the Point_M3 and the Point_H1, thereby reducing the difference in impedance.

FIG. 6 is an explanatory diagram illustrating an example of corresponding circuit information stored in the storage unit 120. In the corresponding circuit information, points and circuit identification information are associated with each other. Here, the circuit identification information is not limited to the serial number shown in FIG. 6, but various information such as matching constants that can identify the circuit can be used.
When the matching circuit 140 obtains the circuit identification information by the matching control signal g13, the matching circuit 140 selects a circuit indicated by the circuit identification information from the circuits C _{1 to} C _n (FIG. 3) (that is, passes a path to the circuit). Switch).
When the matching circuit 140 acquires the circuit identification information “1”, the matching circuit 140 selects the circuit C ₁ that does not perform impedance matching.

Similar to the matching circuit 140, when the matching circuit 160 acquires the circuit identification information by the matching control signal g13, the matching circuit 160 selects a circuit indicated by the circuit identification information from the n circuits included in the matching circuit 160 (that is, the matching circuit 160). , Switch the path to the circuit).
In addition, when the circuit identification information “1” is acquired, the matching circuit 160 selects a circuit that does not perform impedance matching.

The control unit 110 controls each unit of the wireless device 100. In particular, control unit 110 controls the impedances of matching circuits 140 and 160 based on the gain of power amplifier 150 and the setting of TXAGC amplifier 131.
As a result, the control unit 110 can perform finer control not only for each gain of the power amplifier 150 but also for the signal level from the TXAGC amplifier 131 (according to the transmission output level of the radio apparatus 100). . Specifically, the control unit 110 switches the impedance matching process depending on whether or not the power amplifier 150 is near the output level at which the gain is switched, thereby reducing impedance fluctuations when the gain of the power amplifier 150 is switched, and Power consumption in impedance matching can be reduced. Further, when the impedance of the power amplifier 150 changes according to the input level to the power amplifier 150, impedance matching can be performed with higher accuracy.

In addition, the control unit 110 controls the matching circuits 140 and 160 to stop impedance matching when the power amplifier 150 is away from the output level for switching the gain by a predetermined level or more.
Specifically, the control unit 110 causes the matching circuits 140 and 160 to perform impedance matching at Point_L3, Point_M1, Point_M3, and Point_H1 in FIG. Thereby, it is possible to reduce the fluctuation of the impedance when the gain of the power amplifier 150 is switched.
On the other hand, at Point_L1, Point_L2, Point_M2, Point_H2, and Point_H3, which are points separated from the output level at which the power amplifier 150 switches the gain, the control unit 110 performs impedance matching of the matching circuits 140 and 160. Stop. Thereby, power consumption in impedance matching (for example, power consumption in capacitors and inductors included in matching circuits 140 and 160) can be reduced.

Further, when the gain of the power amplifier 150 is changed, the control unit 110 controls the impedances of the matching circuit 140 and the matching circuit 160 again.
Thereby, control unit 110 can appropriately perform impedance matching according to the state after the gain change even when the gain of power amplifier 150 is changed. For example, when the transmission output level is raised at the point of gain switching such as Point_L3 and the transition is made to Point_M2, the control unit 110 performs impedance matching with the matching circuits 140 and 160 according to the gain of the power amplifier 150 after the gain change. Can be performed.

Further, the control unit 110 controls the impedances of the matching circuits 140 and 160 based on the point correspondence information stored in the storage unit 120.
Thereby, control unit 110 can easily detect the point at which power amplifier 150 switches the gain.

  Note that the control unit 110 may be configured as one impedance control device. Alternatively, the control unit 110 may be realized by a CPU (Central Processing Unit) included in the wireless device 100 reading and executing a program from a storage device included in the wireless device 100.

Next, the operation of the wireless device 100 will be described with reference to FIG.
FIG. 7 is a flowchart illustrating a procedure of processing in which the wireless device 100 performs impedance matching. The wireless device 100 starts the process of FIG. 10 every time transmission output is started.
In the process of FIG. 7, first, the transmission unit 130 digitally modulates a digital transmission signal, converts the digital transmission signal into a carrier wave frequency, and further amplifies the signal by the TXAGC amplifier 131 in accordance with the TXAGC control signal g11 from the control unit 110. Output to the circuit 140 (step S101).

  In addition, the control unit 110 reads data corresponding to the gain of the power amplifier 150 and the setting of the TXAGC amplifier 131 from the storage unit 120 (step S102). Specifically, the control unit 110 reads out a point corresponding to the gain control signal g12 output to the power amplifier 150 and the TXAGC control signal g11 output to the TXAGC amplifier 131 from the point correspondence information.

Then, the control unit 110 reads the matching constant corresponding to the obtained point from the corresponding circuit information, and outputs the read matching constant to the matching circuits 140 and 160 as the matching control signal g13 (step S103).
The matching circuits 140 and 160 change the impedance by switching the internal path (circuit to be used) based on the matching control signal g13 from the control unit 110 (step S104).

Next, control unit 110 determines whether or not the gain of power amplifier 150 has been changed (step S105). If it is determined that the gain has not been changed (step S105: YES), the processing in FIG.
On the other hand, when it is determined that the gain has been changed (step S105: NO), the process returns to step S102.

As described above, the control unit 110 controls the impedances of the matching circuits 140 and 160 based on the gain of the power amplifier 150 and the setting of the TXAGC amplifier 131.
Thereby, the control unit 110 can perform finer control according to the signal level from the TXAGC amplifier 131 without being limited to each gain of the power amplifier 150. In particular, the control unit 110 can reduce fluctuations in impedance when the gain of the power amplifier 150 is switched, and can reduce power consumption in impedance matching.

  In addition, the control unit 110 controls the matching circuits 140 and 160 to stop impedance matching when the power amplifier 150 is away from the output level for switching the gain by a predetermined level or more. The control unit 110 causes the matching circuits 140 and 160 to perform impedance matching at a point in the vicinity of the output level at which the power amplifier 150 switches the gain, thereby reducing impedance variation when the gain of the power amplifier 150 is switched. . Further, the control unit 110 can stop the impedance matching of the matching circuits 140 and 160 at a point away from the output level at which the power amplifier 150 switches the gain, thereby reducing the power consumption in the impedance matching. .

Further, when the gain of the power amplifier 150 is changed, the control unit 110 controls the impedances of the matching circuit 140 and the matching circuit 160 again.
Thereby, control unit 110 can appropriately perform impedance matching according to the state after the gain change even when the gain of power amplifier 150 is changed.

The storage unit 120 also stores point correspondence information, which is information in which the gain of the power amplifier 150 and the setting of the TXAGC amplifier 131 are associated with points. Then, the control unit 110 controls the impedances of the matching circuits 140 and 160 based on the point correspondence information stored in the storage unit 120.
Thereby, control unit 110 can easily detect the point at which power amplifier 150 switches the gain.

Next, the minimum configuration of the present invention in this embodiment will be described with reference to FIG.
FIG. 8 is a schematic configuration diagram showing the minimum configuration of the present invention in the radio apparatus (FIG. 1) of the present embodiment. FIG. 8 shows a control unit 110, a TXAGC amplifier 131, and a power amplifier 150 among the units shown in FIG. The matching circuit 340 corresponds to one or both of the matching circuits 140 and 160.

In such a configuration, the control unit 110 controls the impedance of the matching circuit 340 based on the gain of the power amplifier 150 and the setting of the TXAGC amplifier 131.
Thereby, as in the case of the configuration of FIG. 1, the control unit 110 can perform finer control not only for each gain of the power amplifier 150 but also for the signal level from the TXAGC amplifier 131. In particular, the control unit 110 can reduce fluctuations in impedance when the gain of the power amplifier 150 is switched, and can reduce power consumption in impedance matching.

Note that a program for realizing all or part of the functions of the control unit 110 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. You may perform the process of. Here, the “computer system” includes an OS and hardware such as peripheral devices.
Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 100 Radio | wireless apparatus 110 Control part 120 Memory | storage part 130 Transmission part 131 TXAGC amplifier 140 Matching circuit 150 Power amplifier 160 Matching circuit

Claims (7)

An amplifier with variable gain,
A power amplifier that switches the gain according to the required output level;
A matching circuit for impedance matching of the power amplifier;
A control unit that controls the impedance of the matching circuit based on the gain of the power amplifier and the setting of the amplifier that can change the gain;
A wireless device comprising:   The radio apparatus according to claim 1, wherein the control unit controls the matching circuit to stop the impedance matching when the power amplifier is separated from an output level at which a gain is switched by a predetermined level or more.   The radio apparatus according to claim 1, wherein the control unit again controls impedance of the matching circuit when a gain of the power amplifier is changed. A storage unit that stores information associating the gain of the power amplifier and the setting of the amplifier capable of changing the gain with a point indicating the position of the current output level within the range of the output level at the gain of the power amplifier Comprising
4. The wireless device according to claim 1, wherein the control unit controls an impedance of the matching circuit based on the information. 5.   An impedance characterized by controlling an impedance of a matching circuit that performs impedance matching of the power amplifier based on a gain of a power amplifier that amplifies an output of the amplifier having a variable gain and a setting of the amplifier having a variable gain. Control device. An amplifier with variable gain,
A power amplifier that switches the gain according to the required output level;
A matching circuit for impedance matching of the power amplifier;
An impedance control method for a wireless device comprising:
An impedance control method comprising: a control step of controlling the impedance of the matching circuit based on a gain of the power amplifier and a setting of an amplifier having a variable gain. An amplifier with variable gain,
A power amplifier that switches the gain according to the required output level;
A matching circuit for impedance matching of the power amplifier;
A computer for controlling the impedance of a wireless device comprising:
A program for executing a control step of controlling the impedance of the matching circuit based on the gain of the power amplifier and the setting of an amplifier whose gain is variable.

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