JP2012085092A - Wireless device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless circuit which is capable of reducing both mismatching loss and insertion loss between an antenna and a receiver in a plurality of frequency bands.SOLUTION: A wireless device comprises: an antenna; a first series resonant circuit and a first matching circuit which are connected in series between first and second connection points; and a second series resonant circuit and a second matching circuit which are connected in series between third and fourth connection points. The antenna, the first connection point, and the third connection point are connected, and the second connection point and the fourth connection point are connected.

Description

  The present invention particularly relates to a radio circuit capable of matching at a plurality of frequencies and a radio apparatus including the radio circuit.

  When receiving television broadcasts such as terrestrial digital broadcasts, a matching circuit is required to efficiently receive radio waves from an antenna. Conventionally, terrestrial digital broadcasting is provided in the UHF band, and the matching circuit has been designed to be matched in the UHF band.

  On the other hand, in recent years, mobile terminals equipped with a function for receiving and reproducing television broadcasts, such as mobile phones compatible with digital terrestrial broadcasting, have been spreading. A new service called multimedia broadcasting is also planned for mobile terminals. Since this multimedia broadcast is scheduled to be serviced in the VHF band, the matching circuit needs to be designed so that matching can be achieved in the VHF band.

  However, since the mobile terminal is small, it is difficult to mount two antennas for VHF and UHF.

  Methods for solving such problems are described in, for example, Patent Document 1 and Patent Document 2.

  In Patent Document 1, as shown in FIG. 5, a signal received by one antenna is separated into two signals of an AM / FM radio and a mobile phone using a duplexer. In Patent Document 1, the duplexer includes a low-pass filter and a high-pass filter.

  Moreover, in patent document 2, as shown in FIG. 6, the signal received with one antenna is isolate | separated into two signals of the frequency f1 and the frequency f2-3 using a splitter. In Patent Document 2, the duplexer is configured by a band elimination filter.

Japanese Patent No. 2730480 JP 2010-109757 A

  However, in Patent Document 1, since there is one matching circuit, matching cannot be achieved in two frequency bands of AM / FM radio and mobile phone, and mismatch loss between the antenna and the receiver increases. There's a problem. In Patent Document 2, the branching circuit is composed of two band elimination filters. Here, the signal of the frequency f2-3 separated on the frequency f1 side is attenuated by the filter, and the signal of the frequency f1 separated on the frequency f2-3 side is attenuated by the other filter. For this reason, all the attenuation is lost, and there is a problem that the passage loss between the antenna and the reception period increases.

  An object of the present invention is to provide a radio circuit capable of reducing both mismatch loss and pass loss between an antenna and a receiver in a plurality of frequency bands.

  The wireless device of the present invention includes an antenna, a first series resonant circuit and a first matching circuit connected in series between the first and second connection points, and a third and fourth connection point. A second series resonance circuit and a second matching circuit connected in series, wherein the antenna, the first connection point, and the third connection point are connected, and the second connection point and the second connection point A configuration in which four connection points are connected is adopted.

  With this configuration, the demultiplexer, the matching circuit, and the combiner can be realized with a single circuit configuration by demultiplexing the radio signal to obtain matching and then synthesizing again.

  In the wireless device of the present invention, the first series resonant circuit resonates in a first frequency band, the first matching circuit performs impedance matching in a first frequency band, and the second series resonant circuit The second matching circuit resonates in the second frequency band, and impedance matching is performed in the second frequency band.

With this configuration, the first series resonance circuit is short-circuited in the first frequency band and can pass through the first frequency band efficiently, and the second series resonance circuit is in the second frequency band. It becomes a short circuit state, can pass the 2nd frequency band efficiently, and can divide the signal of the 1st frequency band and the 2nd frequency band with low loss. The signal passing through the first series resonance circuit is impedance matched in the first frequency band, the signal passing through the second series resonance circuit is impedance matched in the second frequency band, and then the two signals are By synthesizing, frequency matching can be achieved in two frequency bands.
The radio | wireless apparatus of this invention is provided with the receiving part, and the said receiving part takes the structure connected to the said 2nd connection point and the said 4th connection point.
With this configuration, the receiving unit receives a signal that is demultiplexed with low loss and frequency-matched and synthesized, and therefore can receive a signal with low loss and frequency-matched in two frequency bands.

  The wireless device of the present invention includes an antenna, a first parallel resonant circuit and a third matching circuit connected in series between the fifth and sixth connection points, and a seventh and eighth connection point. A second parallel resonant circuit and a fourth matching circuit connected in series, wherein the antenna, the fifth connection point, and the seventh connection point are connected, and the sixth connection point and the A configuration in which 8 connection points are connected is adopted.

  With this configuration, the demultiplexer, the matching circuit, and the combiner can be realized with one circuit configuration by demultiplexing the radio signal, matching it, and synthesizing it again.

  In the wireless device of the present invention, the first parallel resonant circuit resonates in a second frequency band, the third matching circuit performs impedance matching in the first frequency band, and the second parallel resonant circuit The fourth matching circuit resonates in one frequency band, and impedance matching is performed in the second frequency band.

  With this configuration, the first parallel resonant circuit is open in the second frequency band and can be cut off, and the second parallel resonant circuit is open in the first frequency band. Thus, the first frequency band can be cut off, and the signals of the first frequency band and the second frequency band can be demultiplexed with low loss. The signal that has passed through the first parallel resonance circuit is impedance matched in the first frequency band, the signal that has passed through the second parallel resonance circuit is impedance matched in the second frequency band, and then the two signals are By synthesizing, frequency matching can be achieved in two frequency bands.

The radio | wireless apparatus of this invention is provided with the receiving part, and the said receiving part takes the structure connected to the said 6th connection point and the said 8th connection point.
With this configuration, the receiving unit receives a signal that is demultiplexed with low loss and frequency-matched and synthesized, and therefore can receive a signal with low loss and frequency-matched in two frequency bands.

  The wireless device of the present invention includes an antenna, a third series resonant circuit and a fifth matching circuit connected in series between the ninth and tenth connection points, and an eleventh and twelfth connection point. A third parallel resonance circuit and a sixth matching circuit connected in series, wherein the antenna, the ninth connection point, and the eleventh connection point are connected, and the tenth connection point and the tenth connection point A configuration in which 12 connection points are connected is adopted.

  With this configuration, the demultiplexer, the matching circuit, and the combiner can be realized with a single circuit configuration by demultiplexing the radio signal to obtain matching and then synthesizing again.

  In the wireless device of the present invention, the third series resonance circuit resonates in a first frequency band, the fifth matching circuit impedance-matches in a first frequency band, and the third parallel resonance circuit The sixth matching circuit resonates in the first frequency band and the impedance matching is performed in the second frequency band.

  With this configuration, the third series resonant circuit is short-circuited in the first frequency band and can pass through the first frequency band efficiently, and the third parallel resonant circuit is in the first frequency band. It becomes an open state, the first frequency band can be cut off, and the signals in the first frequency band and the second frequency band can be demultiplexed with low loss. The signal passing through the third series resonance circuit is impedance matched in the first frequency band, the signal passing through the third parallel resonance circuit is impedance matched in the second frequency band, and then the two signals are By synthesizing, frequency matching can be achieved in two frequency bands.

The wireless device of the present invention includes a receiving unit, and the receiving unit is connected to the tenth connection point and the twelfth connection point.
With this configuration, the receiving unit receives a signal that is demultiplexed with low loss and frequency-matched and synthesized, and therefore can receive a signal with low loss and frequency-matched in two frequency bands.

  The wireless device of the present invention includes an antenna, a fourth series resonance circuit, a fourth parallel resonance circuit, and a seventh matching circuit connected in series between the thirteenth and fourteenth connection points, and the fifteenth and fifteenth matching circuits. A fifth series resonant circuit, a fifth parallel resonant circuit, and an eighth matching circuit connected in series between the sixteen connection points, the antenna, the thirteenth connection point, and the fifteenth connection. A point is connected, and the fourteenth connection point and the sixteenth connection point are connected.

  With this configuration, the demultiplexer, the matching circuit, and the combiner can be realized with a single circuit configuration by demultiplexing the radio signal to obtain matching and then synthesizing again.

  In the wireless device of the present invention, the fourth series resonant circuit resonates in a first frequency band, the fourth parallel resonant circuit resonates in a second frequency band, and the seventh matching circuit is a first frequency band. The fifth series resonant circuit resonates in the second frequency band, the fifth parallel resonant circuit resonates in the first frequency band, and the eighth matching circuit The impedance matching is used in the frequency band of 2.

  With this configuration, the fourth series resonance circuit is short-circuited in the first frequency band, and the fourth parallel resonance circuit is open in the second frequency, and allows the first frequency band to pass efficiently. The fifth series resonant circuit is short-circuited at the second frequency band, and the fifth parallel resonant circuit is short-circuited at the first frequency, allowing the second frequency band to pass efficiently. The signals in the first frequency band and the second frequency band can be demultiplexed with low loss. The signal that has passed through the fourth series resonance circuit and the fourth parallel resonance circuit is impedance-matched in the first frequency band, and the signal that has passed through the fifth series resonance circuit and the fifth parallel resonance circuit is Impedance matching is performed in the second frequency band, and then the two signals are combined, whereby frequency matching can be achieved in the two frequency bands.

The radio | wireless apparatus of this invention is provided with the receiving part, and the said receiving part takes the structure connected to the said 14th connection point and the said 16th connection point.
With this configuration, the receiving unit receives a signal that is demultiplexed with low loss and frequency-matched and synthesized, and therefore can receive a signal with low loss and frequency-matched in two frequency bands.

  ADVANTAGE OF THE INVENTION According to this invention, the radio | wireless circuit which can reduce both the mismatch loss and the passage loss between the antenna and receiver in a several frequency band can be provided.

The block diagram which shows the structure of the receiver which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the receiver which concerns on Embodiment 2 of this invention. The block diagram which shows the structure of the receiver which concerns on Embodiment 3 of this invention. The block diagram which shows the structure of the receiver which concerns on Embodiment 4 of this invention. The block diagram which shows the structure of the receiving device of patent document 1 The block diagram which shows the structure of the receiving device of patent document 2

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of radio apparatus 100 according to Embodiment 1 of the present invention. This embodiment will be described by taking as an example a case where the present invention is applied to a mobile phone having a one-segment receiving function, which is one of terrestrial digital broadcasting services, and a multimedia broadcasting receiving function.

  First, an outline of 1Seg will be described. One Seg is a broadcasting service using one of 13 segments constituting the frequency band of terrestrial digital broadcasting. The broadcast station multiplexes the image data and audio data of the broadcast program into a transport stream (TS). The transport stream is subjected to predetermined digital modulation including error correction coding, and the digitally modulated signal is up-converted to a desired frequency and transmitted from the broadcast station side.

  Next, an outline of multimedia will be described. Multimedia broadcasting is scheduled to be provided in the frequency band of 207.5 to 220 MHz after analog television broadcasting is stopped, and services using 13 segments in addition to 1 segment are also possible. Currently, standards are being studied.

  In FIG. 1, the wireless device 100 includes an antenna 101, a series resonance circuit 102, a matching circuit 103, a series resonance circuit 104, a matching circuit 105, and a receiver 106.

  Each configuration will be described in detail below.

  The antenna 101 receives radio signals of the multimedia broadcast of the frequency band f1 and the one-segment broadcast of the frequency band f2.

  The series resonance circuit 102 enters a resonance state (short circuit state) in the frequency band f 1, passes only the frequency band f 1 among the signals received by the antenna 101, and outputs the signal to the matching circuit 103.

  The matching circuit 103 matches the antenna 101 and the receiver 106 in the frequency band f1 and outputs a signal. The output signal is combined with the output signal of the matching circuit 105 and output to the receiver 106.

  The series resonance circuit 104 enters a resonance state (short circuit state) in the frequency band f 2, passes only the frequency band f 2 out of signals received by the antenna 101, and outputs the signal to the matching circuit 105.

  The matching circuit 105 matches the antenna 101 and the receiver 106 in the frequency band f2 and outputs a signal. The output signal is combined with the output signal of the matching circuit 103 and output to the receiver 106.

  The receiver 106 receives a multimedia broadcast signal in the frequency band f1 and a one-segment broadcast signal in the frequency band f2, and performs demodulation and decoding processing.

  Above, description of the structure of the radio | wireless apparatus 100 is finished.

  Next, the operation of radio apparatus 100 having the above configuration will be described.

  The antenna 101 receives radio signals of the multimedia broadcast of the frequency band f1 and the one-segment broadcast of the frequency band f2. The received signal is demultiplexed into the series resonance circuit 102 and the series resonance circuit 104.

  The series resonance circuit 102 passes only the frequency band f1, and the series resonance circuit 104 passes only the frequency band f2. For this reason, since the signal is not attenuated unlike a duplexer configured with a conventional filter, it is possible to reduce a loss when demultiplexing into the frequency band f1 and the frequency band f2.

  The signal in the frequency band f1 that has passed through the series resonant circuit 102 is matched with the frequency band f1 by the matching circuit 103 and output. The signal in the frequency band f2 that has passed through the series resonance circuit 104 is matched with the frequency band f2 by the matching circuit 105 and output. The signals output from matching circuit 103 and matching circuit 105 are combined and output to receiver 106.

  Since the signal input to the receiver 106 is a combination of signals matched in the frequency band f1 and the frequency band f2, mismatch loss between the antenna 101 and the receiver 106 can be reduced.

  As described above, according to the present embodiment, the multimedia broadcast signal in the frequency band f1 received by the antenna and the one-segment broadcast signal in the frequency band f2 are demultiplexed without being attenuated. can do. In addition, since the signals after the demultiplexing are matched in the frequency band f1 and the frequency band f2, respectively, and synthesized, the signal input to the receiver 106 is matched in the frequency band f1 and the frequency band f2, and the two frequencies Mismatch loss between the antenna 101 and the receiver 106 in the bands f1 and f2 can be reduced. In this embodiment, the matching circuit is connected in the order next to the series resonance circuit. However, this connection order is not limited, and the same effect can be obtained even in the configuration in which the series resonance circuit is connected next to the matching circuit. Can do.

(Embodiment 2)
FIG. 2 is a block diagram showing a configuration of radio apparatus 200 according to Embodiment 2 of the present invention. Note that in the configuration of the wireless apparatus in this embodiment, the same components as those in FIG. 1 are not described, and the reference numerals in FIG. 1 are used in the description of FIG.

  In FIG. 2, the wireless device 200 includes an antenna 101, a parallel resonant circuit 201, a matching circuit 103, a parallel resonant circuit 202, a matching circuit 105, and a receiver 106.

  Each configuration will be described in detail below.

  The parallel resonance circuit 201 enters a resonance state (open state) in the frequency band f <b> 2, blocks only the frequency band f <b> 2 of the signal received by the antenna 101, and outputs it to the matching circuit 103.

  The parallel resonance circuit 202 enters a resonance state (open state) in the frequency band f 1, cuts only the frequency band f 1 among the signals received by the antenna 101, and outputs it to the matching circuit 105.

  Above, description of the structure of the radio | wireless apparatus 200 is finished.

  Next, the operation of radio apparatus 200 having the above configuration will be described.

The antenna 101 receives radio signals of the multimedia broadcast of the frequency band f1 and the one-segment broadcast of the frequency band f2. The received signal is demultiplexed into the parallel resonance circuit 201 and the parallel resonance circuit 202. The parallel resonance circuit 201 blocks only the frequency band f2, and the parallel resonance circuit 202 blocks only the frequency band f1. As a result, all signals in the frequency band f1 pass through the parallel resonant circuit 201 and are output to the matching circuit 103. All signals in the frequency band f2 pass through the parallel resonance circuit 202 and are output to the matching circuit 105. For this reason, since the signal is not attenuated unlike a duplexer configured with a conventional filter, it is possible to reduce a loss when demultiplexing into the frequency band f1 and the frequency band f2.

  The signal in the frequency band f1 that has passed through the parallel resonant circuit 201 is matched with the frequency band f1 by the matching circuit 103 and output. The signal in the frequency band f2 that has passed through the parallel resonance circuit 202 is matched with the frequency band f2 by the matching circuit 105 and output. The signals output from matching circuit 103 and matching circuit 105 are combined and output to receiver 106.

  Since the signal input to the receiver 106 is a combination of signals matched in the frequency band f1 and the frequency band f2, mismatch loss between the antenna 101 and the receiver 106 can be reduced.

  As described above, according to the present embodiment, the multimedia broadcast signal in the frequency band f1 received by the antenna and the one-segment broadcast signal in the frequency band f2 are demultiplexed without being attenuated. can do. In addition, since the signals after the demultiplexing are matched in the frequency band f1 and the frequency band f2, respectively, and synthesized, the signal input to the receiver 106 is matched in the frequency band f1 and the frequency band f2, and the two frequencies Mismatch loss between the antenna 101 and the receiver 106 in the bands f1 and f2 can be reduced. In the present embodiment, the matching circuit is connected in the order next to the parallel resonant circuit. However, this connection order is not limited, and the same effect can be obtained even in the configuration in which the parallel resonant circuit is connected next to the matching circuit. Can do.

(Embodiment 3)
FIG. 3 is a block diagram showing a configuration of radio apparatus 300 according to Embodiment 3 of the present invention. Note that in the configuration of the wireless apparatus in this embodiment, the same components as those in FIGS. 1 and 2 are not described, and the reference numerals in FIGS. 1 and 2 are used in the description of FIG.

  In FIG. 3, the wireless device 300 includes an antenna 101, a series resonance circuit 102, a matching circuit 103, a parallel resonance circuit 202, a matching circuit 105, and a receiver 106.

  Next, the operation of radio apparatus 300 having the above configuration will be described.

The antenna 101 receives radio signals of the multimedia broadcast of the frequency band f1 and the one-segment broadcast of the frequency band f2. The received signal is demultiplexed into the series resonance circuit 102 and the parallel resonance circuit 202. The series resonance circuit 102 passes only the frequency band f1, and the parallel resonance circuit 202 blocks only the frequency band f1. As a result, all signals in the frequency band f1 pass through the series resonance circuit 102 and are output to the matching circuit 103. All signals in the frequency band f2 pass through the parallel resonance circuit 202 and are output to the matching circuit 105. For this reason, since the signal is not attenuated unlike a duplexer configured with a conventional filter, it is possible to reduce a loss when demultiplexing into the frequency band f1 and the frequency band f2.

  The signal in the frequency band f1 that has passed through the series resonant circuit 102 is matched with the frequency band f1 by the matching circuit 103 and output. The signal in the frequency band f2 that has passed through the parallel resonance circuit 202 is matched with the frequency band f2 by the matching circuit 105 and output. The signals output from matching circuit 103 and matching circuit 105 are combined and output to receiver 106.

  Since the signal input to the receiver 106 is a combination of signals matched in the frequency band f1 and the frequency band f2, mismatch loss between the antenna 101 and the receiver 106 can be reduced.

  As described above, according to the present embodiment, the multimedia broadcast signal in the frequency band f1 received by the antenna and the one-segment broadcast signal in the frequency band f2 are demultiplexed without being attenuated. can do. In addition, since the signals after the demultiplexing are matched in the frequency band f1 and the frequency band f2, respectively, and synthesized, the signal input to the receiver 106 is matched in the frequency band f1 and the frequency band f2, and the two frequencies Mismatch loss between the antenna 101 and the receiver 106 in the bands f1 and f2 can be reduced. In this embodiment, the matching circuit is connected to the matching circuit after the series resonance circuit and the matching circuit is connected to the matching circuit next to the parallel resonance circuit. A similar effect can be obtained with a configuration in which parallel resonant circuits are connected. In the present embodiment, the same effect can be obtained by replacing the series resonant circuit 102 with a parallel resonant circuit in the frequency band f2 and replacing the parallel resonant circuit 202 with a series resonant circuit in the frequency band f2.

(Embodiment 4)
FIG. 4 is a block diagram showing a configuration of radio apparatus 400 according to Embodiment 4 of the present invention. Note that in the configuration of the wireless device in this embodiment, the same components as those in FIGS. 1, 2, and 3 are not described, and in the description of FIG. 4, FIGS. Is used.

  In FIG. 4, the wireless device 400 includes an antenna 101, a series resonance circuit 102, a parallel resonance circuit 201, a matching circuit 103, a series resonance circuit 104, a parallel resonance circuit 202, a matching circuit 105, and a receiver 106. And have.

  Next, the operation of radio apparatus 400 having the above configuration will be described.

The antenna 101 receives radio signals of the multimedia broadcast of the frequency band f1 and the one-segment broadcast of the frequency band f2. The received signal is demultiplexed into the series resonance circuit 102 and the series resonance circuit 104. The series resonance circuit 102 passes only the frequency band f1, and the parallel resonance circuit 201 blocks only the frequency band f2. Further, only the frequency band f2 is passed through the series resonance circuit 104, and only the frequency band f1 is blocked at the parallel resonance circuit 202. As a result, all signals in the frequency band f1 pass through the series resonant circuit 102 and the parallel resonant circuit 201 and are output to the matching circuit 103. All signals in the frequency band f2 pass through the series resonant circuit 104 and the parallel resonant circuit 202 and are output to the matching circuit 105. For this reason, the signal is not attenuated unlike a duplexer configured with a conventional filter, and even if a signal in the frequency band f2 enters the series resonant circuit 102, the parallel resonant circuit 201 cuts off the signal. Even if a signal in the frequency band f1 enters the series resonance circuit 104, it is blocked by the parallel resonance circuit 202 and is not output to the matching circuit 105. Therefore, the loss when demultiplexing into the frequency band f1 and the frequency band f2 Can be reduced.

  The signal in the frequency band f1 that has passed through the series resonant circuit 102 and the parallel resonant circuit 201 is matched with the frequency band f1 by the matching circuit 103 and output. The signal in the frequency band f2 that has passed through the series resonant circuit 104 and the parallel resonant circuit 202 is matched with the frequency band f2 by the matching circuit 105 and output. The signals output from matching circuit 103 and matching circuit 105 are combined and output to receiver 106.

  Since the signal input to the receiver 106 is a combination of signals matched in the frequency band f1 and the frequency band f2, mismatch loss between the antenna 101 and the receiver 106 can be reduced.

  As described above, according to the present embodiment, the multimedia broadcast signal in the frequency band f1 received by the antenna and the one-segment broadcast signal in the frequency band f2 are demultiplexed without being attenuated. can do. In addition, since the signals after the demultiplexing are matched in the frequency band f1 and the frequency band f2, respectively, and synthesized, the signal input to the receiver 106 is matched in the frequency band f1 and the frequency band f2, and the two frequencies Mismatch loss between the antenna 101 and the receiver 106 in the bands f1 and f2 can be reduced. In this embodiment, the series resonance circuit, the parallel resonance circuit, and the matching circuit are connected in this order, but this connection order is not limited, and even in the configuration in which the series resonance circuit and the parallel resonance circuit are connected next to the matching circuit, Similar effects can be obtained.

  The radio circuit according to the present invention is particularly suitable for reducing mismatch loss and passing loss between an antenna and a receiver.

100, 200, 300, 400 Wireless device 101 Antenna 102, 104 Series resonant circuit 103, 105 Matching circuit 106 Receiver 201, 202 Parallel resonant circuit

Claims (12)

An antenna,
A first series resonant circuit and a first matching circuit connected in series between the first and second connection points;
A second series resonant circuit and a second matching circuit connected in series between the third and fourth connection points,
The antenna, the first connection point and the third connection point are connected;
A wireless device in which the second connection point and the fourth connection point are connected. The wireless device according to claim 1,
The first series resonant circuit resonates in a first frequency band;
The first matching circuit performs impedance matching in a first frequency band;
The second series resonant circuit resonates in a second frequency band;
The second matching circuit is a wireless device for impedance matching in a second frequency band. The wireless device according to claim 1 or 2, wherein
With a receiver
The receiving unit is a wireless device connected to the second connection point and the fourth connection point. An antenna,
A first parallel resonant circuit and a third matching circuit connected in series between the fifth and sixth connection points;
A second parallel resonant circuit and a fourth matching circuit connected in series between the seventh and eighth connection points,
The antenna, the fifth connection point and the seventh connection point are connected;
A wireless device to which the sixth connection point and the eighth connection point are connected. The wireless device according to claim 4,
The first parallel resonant circuit resonates in a second frequency band;
The third matching circuit performs impedance matching in a first frequency band;
The second parallel resonant circuit resonates in a first frequency band;
The fourth matching circuit is a wireless device that performs impedance matching in a second frequency band. A wireless device according to claim 4 or claim 5, wherein
With a receiver
The receiving unit is a wireless device connected to the sixth connection point and the eighth connection point. An antenna,
A third series resonant circuit and a fifth matching circuit connected in series between the ninth and tenth connection points;
A third parallel resonant circuit and a sixth matching circuit connected in series between the eleventh and twelfth connection points;
The antenna, the ninth connection point, and the eleventh connection point are connected;
A wireless device to which the tenth connection point and the twelfth connection point are connected. The wireless device according to claim 7, wherein
The third series resonant circuit resonates in a first frequency band;
The fifth matching circuit performs impedance matching in a first frequency band;
The third parallel resonant circuit resonates in a first frequency band;
The sixth matching circuit is a wireless device that performs impedance matching in a second frequency band. A wireless device according to claim 7 or claim 8, wherein
With a receiver
The receiving unit is a wireless device connected to the tenth connection point and the twelfth connection point. An antenna,
A fourth series resonant circuit, a fourth parallel resonant circuit, and a seventh matching circuit connected in series between the thirteenth and fourteenth connection points;
A fifth series resonant circuit, a fifth parallel resonant circuit, and an eighth matching circuit connected in series between the fifteenth and sixteenth connection points;
The antenna, the thirteenth connection point and the fifteenth connection point are connected;
A wireless device to which the fourteenth connection point and the sixteenth connection point are connected. The wireless device according to claim 10, wherein the fourth series resonant circuit resonates in a first frequency band,
The fourth parallel resonant circuit resonates in a second frequency band;
The seventh matching circuit performs impedance matching in a first frequency band;
The fifth series resonant circuit resonates in a second frequency band;
The fifth parallel resonant circuit resonates in a first frequency band;
The eighth matching circuit is a wireless device that performs impedance matching in a second frequency band. A wireless device according to claim 10 or claim 11,
With a receiver
The receiver is a wireless device connected to the fourteenth connection point and the sixteenth connection point.

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