JP6687243B2 - Wireless communication device - Google Patents

Description

  The present invention relates to a wireless communication device.

  Conventionally, an antenna, a high frequency circuit, and a first matching circuit that performs matching such that the antenna and the high frequency circuit resonate at a transmission frequency when connected to the antenna and the high frequency circuit are provided. There is a mobile terminal device. A second matching circuit that performs matching so that the antenna and the high-frequency circuit resonate at a reception frequency when connected to the antenna and the high-frequency circuit; and the first matching circuit or the second matching circuit. And a switch circuit for connecting one of the two to the antenna and the high-frequency circuit. Which of the first matching circuit and the second matching circuit the switch circuit connects to the antenna and the high-frequency circuit based on a proximity sensor that detects an object and a detection result of the proximity sensor. Is further provided with a control means for controlling (see, for example, Patent Document 1).

JP, 2012-239108, A

  By the way, the conventional mobile terminal device can reduce the SAR when one antenna radiates a radio wave, but does not assume to reduce the SAR when a plurality of antennas radiate at the same time. You cannot do it.

  Then, it aims at providing the radio | wireless communication apparatus which can reduce SAR when several antennas radiate | emit simultaneously.

  A wireless communication device according to an embodiment of the present invention, when the wireless communication device performs a voice call, a substrate having a first surface facing a human body side and a second surface opposite to the first surface, The first antenna, which is disposed on the first end side of the substrate and used for either voice communication or data communication, is disposed on the second end side opposite to the first end of the substrate. A second antenna provided for use in data communication, a third antenna arranged near the second antenna for use in data communication by a communication method different from that of the second antenna, and a feeding point of the second antenna A switch having a first terminal connected to the first terminal, a second terminal and a third terminal switchably connected to the first terminal, and a matching circuit connected to the second terminal. When the antenna performs data communication, the switch is A matching circuit that sets the resonance frequency of the second antenna to a resonance frequency different from the resonance frequency of the third antenna when one terminal is connected to the second terminal, and an adjustment circuit connected to the third terminal When the switch connects the first terminal and the third terminal when the third antenna performs data communication, the second antenna resonates with the third antenna. And an adjusting circuit for adjusting the directivity of the third antenna so as to face the second surface side of the substrate.

  A wireless communication device capable of reducing SAR when a plurality of antennas radiate simultaneously can be provided.

FIG. 3 is a perspective view showing an electronic device 10 including the wireless communication device of the embodiment. It is a figure which shows the radio | wireless communication apparatus 100 of embodiment. FIG. 6 is a diagram illustrating an operation when a voice call and a data communication by a WLAN method are performed by the wireless communication device 100. FIG. 9 is a diagram illustrating an operation when the wireless communication device 100 performs data communication by the LTE-MIMO system. 6 is a diagram showing a simulation model used in an electromagnetic field simulation of the wireless communication device 100. FIG. FIG. 6 is a diagram showing a part of the sub antenna 120 and the WLAN antenna 130, and a switch 140, a matching circuit 150, an adjusting circuit 160, and a matching circuit 180. It is a figure which shows the directivity obtained by the simulation model.

  An embodiment to which the wireless communication device of the present invention is applied will be described below.

<Embodiment>
FIG. 1 is a perspective view showing an electronic device 10 including the wireless communication device according to the embodiment. In the present embodiment, description will be made using an XYZ coordinate system as shown in FIG. A common XYZ coordinate system is used also in the other drawings shown below. In addition, the XY plane view is referred to as a plane view.

  The electronic device 10 is, for example, a smartphone terminal or a mobile phone terminal. The electronic device 10 may be any device that has a function of making a voice call.

  The electronic device 10 includes a touch panel 12 and a display panel 13 which are arranged on one surface (a surface on the Z axis positive direction side) side of the housing 11. The touch panel 12 is arranged on the Z axis positive direction side (front surface side) with respect to the display panel 13. The display panel 13 displays various buttons, sliders, and the like by GUI (Graphic User Interface).

  The electronic device 10 also includes a speaker 14 and a microphone 15 arranged on one surface (surface on the Z axis positive direction side) side of the housing 11. A user who makes a voice call using the speaker 14 and the microphone 15 of the electronic device 10 puts the speaker 14 on his ear and places the microphone 15 near his mouth.

  FIG. 2 is a diagram showing the wireless communication device 100 of the embodiment.

  The wireless communication device 100 includes a substrate 50, a main antenna 110, a sub antenna 120, a WLAN antenna 130, a switch 140, a matching circuit 150, an adjusting circuit 160, and a controller 170. In the following, the power supply for supplying power to the main antenna 110, the sub antenna 120, and the WLAN antenna 130 is indicated by an AC symbol.

  The board 50 is disposed inside the housing 11 (see FIG. 1), and is, for example, a FR4 (Flame Retardant type 4) standard wiring board. The substrate 50 has a ground plane 51. The ground plane 51 is provided on the surface of the substrate 50 on the Z axis positive direction side, and is therefore indicated by a broken line. The ground plane 51 may be provided on the surface of the substrate 50 on the negative side of the Z axis, or may be provided on the inner layer surface of the substrate 50.

  A main antenna 110, a sub antenna 120, a WLAN antenna 130, a switch 140, a matching circuit 150, and an adjustment circuit 160 are provided on the surface of the substrate 50 on the Z axis negative direction side.

  The main antenna 110 is provided at an end of the board 50 on the negative side of the Y-axis of the surface on the negative side of the Z-axis. The main antenna 110 is an example of a first antenna used for either voice call communication or data communication. When the user uses the speaker 14 and the microphone 15 (see FIG. 1) to make a voice call, the electronic device 10 is placed on the side of the user's head, so that the SAR (Specific In order to suppress the influence of (Absorption Rate), the main antenna 110 is arranged on the side close to the microphone 15.

  The main antenna 110 is a T-shaped antenna, extends from the power feeding unit 111 in the negative Y-axis direction, branches at the branching unit 112, and extends to the ends 113 and 114 in the positive X-axis direction and the negative X-axis direction. is doing. The power feeding unit 111 is located near the end of the ground plane 51 on the Y axis negative direction side in plan view. The ends 113 and 114 are located near the edges of the substrate 50 on the X axis positive direction side and the X axis negative direction side, respectively.

  The length from the branch portion 112 to the end portion 114 is longer than the length from the branch portion 112 to the end portion 113. The L-shaped portion from the power feeding portion 111 to the end portion 114 via the branch portion 112 functions as a monopole antenna having a resonance frequency of f1. f1 is, for example, 800 MHz.

  The L-shaped portion from the power feeding portion 111 to the end portion 113 via the branch portion 112 functions as a monopole antenna having a resonance frequency of f2. f2 is 2 GHz as an example. The base station side determines which of f1 and f2 is used.

  The main antenna 110 independently performs communication when performing voice call communication and data transmission communication. As an example, the main antenna 110 uses WCDMA (registered trademark) (Wideband Code Division Multiple Access: 3G (Generation))-SISO (Single-Input-Single) when performing voice call communication and communication for transmitting data. -Output) communication is performed.

  Further, the main antenna 110 cooperates with the sub antenna 120 when performing communication for receiving data, and performs communication (data reception) by an LTE (Long Term Evolution) -MIMO (Multi-Input Multi-Output) method. I do.

  The sub-antenna 120 is provided at the end of the Y-axis positive direction side of the surface of the substrate 50 on the Z-axis negative direction side. The sub antenna 120 is an example of a second antenna used exclusively for reception (data reception) of data communication. The sub antenna 120 cooperates with the main antenna 110 to perform communication (data reception) by the LTE-MIMO method. The sub antenna 120 is arranged on the opposite side of the main antenna 110 in the Y-axis direction of the substrate 50.

  The sub-antenna 120 is a T-shaped antenna, extends from the power feeding portion 121 in the Y-axis positive direction, branches at the branching portion 122, and extends to the end portions 123 and 124 in the X-axis positive direction and the X-axis negative direction. is doing. The power feeding unit 121 is located near the end of the ground plane 51 on the positive side of the Y axis in plan view. The ends 123 and 124 are located near the ends of the substrate 50 on the X-axis positive direction side and the X-axis negative direction side, respectively.

  The length from the branch portion 122 to the end portion 124 is longer than the length from the branch portion 122 to the end portion 123. The L-shaped portion from the power feeding portion 121 to the end portion 124 via the branch portion 122 functions as a monopole antenna having a resonance frequency of f1. f1 is, for example, 800 MHz.

  The L-shaped part from the power feeding part 121 to the end part 123 via the branch part 122 functions as a monopole antenna having a resonance frequency of f2. f2 is 2 GHz as an example. The base station side determines which of f1 and f2 is used.

  The WLAN antenna 130 is an L-shaped monopole antenna and is an example of a third antenna. The WLAN antenna 130 is an antenna that performs data communication (transmission and reception) by a WLAN (Wireless Local Area Network) communication method. The communication frequency of the WLAN antenna 130 is f3, which is different from the communication frequencies f1 and f2 of the main antennas 110 and 120. f3 is, for example, 5 GHz.

  The WLAN antenna 130 extends in the Y-axis positive direction from the power feeding unit 131, is bent in the X-axis negative direction side at the bending unit 132, and extends in the X-axis negative direction to the end 133. The power supply unit 131 is located near the end of the ground plane 51 on the positive side of the Y axis in plan view. Further, the section between the bent portion 132 and the end 133 is parallel to the section between the branch section 122 and the end section 124 of the sub antenna 120 with a predetermined interval (for example, 5 mm). The end portion 133 is located near the end side of the substrate 50 on the negative side in the X-axis direction.

  The switch 140 is a switch having three terminals 141, 142, and 143, and switches the connection destination of the terminal 141 to either the terminal 142 or 143. The switching of the switch 140 is performed by the control unit 170. The terminal 141 is an example of a first terminal, the terminal 142 is an example of a second terminal, and the terminal 143 is an example of a third terminal.

  The terminal 141 is connected to the power feeding unit 121, the terminal 142 is connected to the matching circuit 150, and the terminal 143 is connected to the adjustment circuit 160. Therefore, the connection destination of the power feeding unit 121 is switched by the switch 140 to either the matching circuit 150 or the adjustment circuit 160.

  The matching circuit 150 is connected to the sub antenna 120 by the switch 140 when the sub antenna 120 receives data, and matches the communication frequency of the sub antenna 120 to f1 and f2. Sub-antenna 120 is not coupled to WLAN antenna 130 when communicating at communication frequencies f1 and f2.

  When the switch 140 connects the sub antenna 120 and the adjustment circuit 160 when the WLAN antenna 130 performs data communication, the adjustment circuit 160 adjusts the impedance of the sub antenna 120 so that the sub antenna 120 resonates with the WLAN antenna 130. In addition, the directivity of the WLAN antenna 130 is adjusted so as to face the negative Z-axis direction.

  The adjustment circuit 160 includes an inductance or a capacitance, and when connected to the sub antenna 120 by the switch 140, adjusts the resonance frequency of the sub antenna 120 to the communication frequency f3 of the WLAN antenna 130. In this way, the resonance frequency of the sub antenna 120 is adjusted to f3 by the adjustment circuit 160, so that the sub antenna 120 and the WLAN antenna 130 are coupled and the directivity can be controlled. In order to match the resonance frequency of the sub antenna 120 with the communication frequency f3, either the fundamental wave or the harmonic of the resonance frequency of the sub antenna 120 may be matched with the communication frequency f3. Therefore, for example, by lowering the frequency of one of the harmonics of the sub antenna 120 to 5 GHz, the sub antenna 120 and the WLAN antenna 130 can resonate.

  The Z-axis negative direction side is the side opposite to the side where the speaker 14 and the microphone 15 of the electronic device 10 (see FIG. 1) are present. That is, it is the side opposite to the side where the touch panel 12 and the display panel 13 of the electronic device 10 are present (the back side of the electronic device 10).

  The directivity of the sub-antenna 120 and the WLAN antenna 130 is directed toward the negative Z-axis side means that the directivity distribution of the sub-antenna 120 and the WLAN antenna 130 is biased toward the negative Z-axis side, or the sub-antenna 120 and the WLAN are The directivity of the antenna 130 is to have a null point on the Z axis positive direction side. The adjustment of the distribution of directivity will be described later.

  The control unit 170 is implemented by, for example, a CPU (Central Processing Unit). For example, the control unit 170 is realized as a part of the function of the CPU that controls the high-frequency wireless communication of the electronic device 10.

  Therefore, the control unit 170 receives a signal indicating a mode in which the wireless communication device 100 makes a voice call and a signal indicating a mode in which data communication is performed by the LTE-MIMO system. The control unit 170 switches the switch 140 based on these signals.

  The control unit 170 connects the terminals 141 and 142 when the sub antenna 120 receives data. As a result, the sub antenna 120 and the matching circuit 150 are connected. Further, the control unit 170 connects the terminals 141 and 143 when the WLAN antenna 130 performs data communication. As a result, the sub antenna 120 and the adjustment circuit 160 are connected.

  FIG. 3 is a diagram illustrating an operation when the wireless communication device 100 performs a voice call and data communication by the WLAN system. FIG. 3A shows a connection state of the switch 140 in the wireless communication device 100, and FIG. 3B shows a state in which the user holds the electronic device 10 in his left hand and puts the speaker 14 on his left ear. , Shows a state in which a telephone call is made and data communication is performed by the WLAN method. Note that FIG. 3B schematically illustrates the electronic device 10, the wireless communication device 100, the main antenna 110, the sub antenna 120, and the WLAN antenna 130.

  The voice call is performed by communication using the main antenna 110. Further, when performing data communication by the WLAN method, as shown in FIG. 3A, the switch 140 connects the power feeding section 121 of the sub antenna 120 and the adjustment circuit 160 to connect the sub antenna 120 to the WLAN antenna 130. The directivity is controlled by resonating at the communication frequency f3. Therefore, as shown in FIG. 3B, the directivity of the WLAN antenna 130 (using the sub-antenna 120 and the adjusting circuit 160) is set so as to face the back side of the electronic device 10 as indicated by an ellipse and an arrow. Is adjusted to, the influence of SAR on the head is reduced.

  Here, when a voice call communication is performed by the main antenna 110, since the radio waves are radiated to the lower part of the head (the part below the mouth), the influence of the SAR is reduced, which causes a problem. Don't Note that this is the same when only the voice call communication is performed using the main antenna 110.

  FIG. 4 is a diagram illustrating an operation when the wireless communication device 100 performs data communication by the LTE-MIMO method. FIG. 4A shows a connection state of the switch 140 in the wireless communication device 100, and FIG. 4B shows that the user holds the electronic device 10 in his left hand and uses the main antennas 110 and 120. The state where data communication is performed by the LTE-MIMO system is shown. In FIG. 4B, since the user is not making a voice call, the electronic device 10 is not in contact with the ear, and is in front of the user (hand) apart from the head.

  When performing data communication by the LTE-MIMO method, the switch 140 connects the power feeding unit 121 of the sub antenna 120 and the matching circuit 150 as illustrated in FIG. 4A. As a result, the sub-antenna 120 enters a state in which it can communicate at the resonance frequencies f1 and f2. Data communication by the LTE-MIMO system is realized by the main antenna 110 and the sub antenna 120.

  When the user holds the electronic device 10 in his / her hand and is performing data communication by a plurality of communication systems such as the LTE-MIMO system and the WLAN system, radio waves are radiated from the main antenna 110 and the WLAN antenna 130. Since 10 is far away from the human body, the effect of SAR is negligible.

  FIG. 5 is a diagram showing a simulation model used in the electromagnetic field simulation of the wireless communication device 100. FIG. 6 is a diagram showing a part of the sub antenna 120 and the WLAN antenna 130, and the switch 140, the matching circuit 150, the adjusting circuit 160, and the matching circuit 180. FIG. 6 is a diagram in which a switch 140, a matching circuit 150, an adjusting circuit 160, and a matching circuit 180 are added to an enlarged view of a part of the sub antenna 120 and the WLAN antenna 130 of the simulation model shown in FIG.

  The matching circuit 180 is a circuit for matching the impedance of the WLAN antenna 130, and includes a capacitor or an inductor. Although the matching circuit 180 is not shown in FIGS. 2 to 4, as shown in FIG. 5, the matching circuit 180 may be appropriately inserted between the power feeding section 131 of the WLAN antenna 130 and the ground plane 51A.

  FIG. 5 shows the ground plane 51A, the sub antenna 120, the WLAN antenna 130, and the adjustment circuit 160. The ground plane 51A is a conductor having a width of 50 mm in the X-axis direction and a length of 100 mm in the Y-axis direction. In the simulation model shown in FIG. 5, the ground plane 51A is a flat conductor parallel to the XZ plane. The adjustment circuit 160 is provided between the ground plane 51A and the sub antenna 120.

  As shown in FIG. 6, the length between the power feeding portion 131 and the bent portion 132 of the WLAN antenna 130 is 5 mm. The length of the section between the branch section 122 and the end section 124 of the sub antenna 120 and the section between the bent section 132 and the end section 133 of the WLAN antenna 130 extending in parallel in the X-axis direction is 13 mm. Is. Therefore, the length of the WLAN antenna 130 is 18 mm. The end portion 124 is located on the X axis negative direction side of the end portion 133.

  Further, the interval between the branch portion 122 and the end portion 124 of the sub antenna 120 and the section between the bent portion 132 and the end portion 133 of the WLAN antenna 130 in the Y-axis direction is 5 mm.

The adjustment circuit 160 is composed of an inductor, and when it is connected to the sub-antenna 120 by the switch 140, one frequency of the harmonics of the sub-antenna 120 is lowered to 5 GHz. When the directivity of the WLAN antenna 130 was obtained with the sub antenna 120 and the adjusting circuit 160 connected, the directivity as shown in FIG. 7 was obtained.

  FIG. 7 is a diagram showing the directivity obtained by the simulation model. In FIG. 7, the directivity of the WLAN antenna 130 when the sub-antenna 120 and the adjustment circuit 160 are connected by the switch 140 is shown by a broken line.

  For comparison, the solid line indicates the directivity of the WLAN antenna 130 in the state where the switch 140 connects the sub-antenna 120 and the matching circuit 150. When the switch 140 connects the sub antenna 120 and the matching circuit 150, the sub antenna 120 and the WLAN antenna 130 do not resonate.

  As shown in FIG. 7, the directivity indicated by the solid line for comparison is substantially equal in the YZ plane. On the other hand, the directivity shown by the broken line has a larger gain on the Z axis negative direction side than the directivity shown by the solid line, and has a null point on the Z axis positive direction side. Therefore, it was confirmed that the directivity of the WLAN antenna 130 was directed to the Z-axis negative direction side.

  As described above, according to the embodiment, when the WLAN antenna 130 performs data communication, the switch 140 connects the sub antenna 120 and the adjustment circuit 160, and the sub antenna 120 resonates with the WLAN antenna 130. And the directivity of the WLAN antenna 130 is adjusted to face the negative Z-axis side.

  Therefore, even if the wireless communication device 100 performs data communication in the voice communication by the main antenna 110 and the WLAN antenna 130 performs data communication by the WLAN method, the directivity of the WLAN antenna 130 has a directivity of the wireless communication device 100. The SAR can be reduced because it can be switched so as to face the back side (the direction away from the head).

  Therefore, it is possible to provide the wireless communication device 100 capable of reducing the SAR when a plurality of antennas radiate simultaneously.

  Further, conventionally, there is a case where the output is reduced in order to reduce the SAR. However, even if the SAR is reduced by such a method, the radiation characteristic is deteriorated, and therefore, an essential solution to the problem. Has not reached.

  In such a case, the wireless communication device 100 according to the first embodiment switches the directivity of the WLAN antenna 130 so as to face the back side of the wireless communication device 100, so that the SAR is reduced without reducing the output. be able to.

  The communication frequencies of the main antenna 110, the sub antenna 120, and the WLAN antenna 130 described above are examples, and even when communication is performed at a communication frequency other than the above, each part of the main antenna 110, the sub antenna 120, and the WLAN antenna 130. This can be dealt with by changing the dimensions and the like.

  In the above, the WLAN antenna 130 is shown as an example of the third antenna, but the WLAN antenna 130 may be used as an antenna of a communication system other than WLAN.

The dimensions of the sub antenna 120 and the WLAN antenna 130 shown in FIG. 6 are examples. The length of the section between the branch section 122 and the end section 124 of the sub antenna 120 and the section between the bent section 132 and the end section 133 of the WLAN antenna 130 extending in parallel in the X-axis direction is: It is not limited to 13 mm. If the wavelength at the communication frequency f3 of the WLAN antenna 130 is λ ₃ , the length of the section extending in parallel is, for example, about λ ₃ × (2/3) or more and λ ₃ × (4/5) or less. Good. The interval in the Y-axis direction between the sections extending in parallel may be about λ ₃ × (1/4) or more and λ ₃ × (1/3) or less.

  Although the form in which the wireless communication device 100 includes the main antenna 110 has been described above, a device that does not include the main antenna 110 may be regarded as the wireless communication device 100.

  In the above description, the adjustment circuit 160 includes an inductor, and the frequency of one of the harmonics of the sub-antenna 120 is reduced to 5 GHz so that the sub-antenna 120 and the WLAN antenna 130 resonate with each other.

  However, the adjustment circuit 160 may adjust the resonance frequency of the sub-antenna 120 so that it becomes equal to the resonance frequency of the WLAN antenna 130. In such a case, the adjustment circuit 160 may include an inductor or a capacitor so that the resonance frequency of the sub antenna 120 can be adjusted appropriately.

The wireless communication device according to the exemplary embodiment of the present invention has been described above. However, the present invention is not limited to the specifically disclosed embodiment, and does not depart from the scope of the claims. Various modifications and changes are possible.
The following supplementary notes are disclosed regarding the above-described embodiment.
(Appendix 1)
A wireless communication device,
A substrate having a first surface facing the human body when the wireless communication device makes a voice call, and a second surface opposite to the first surface;
A first antenna disposed on the first end side of the substrate and used for either voice communication or data communication;
A second antenna disposed on the second end side of the substrate opposite to the first end and used for data communication;
A third antenna arranged near the second antenna and used for data communication by a communication method different from that of the second antenna;
A switch having a first terminal connected to a feeding point of the second antenna, and a second terminal and a third terminal switchably connected to the first terminal;
A matching circuit connected to the second terminal, wherein when the switch connects the first terminal and the second terminal when the second antenna performs data communication, the resonance frequency of the second antenna is changed. A matching circuit for setting a resonance frequency different from the resonance frequency of the third antenna;
An adjusting circuit connected to the third terminal, wherein when the switch connects the first terminal and the third terminal when the third antenna performs data communication, the second antenna operates as the third terminal. An adjustment circuit that adjusts the impedance of the second antenna so as to resonate with the antenna and adjusts the directivity of the third antenna so as to face the second surface side of the substrate.
(Appendix 2)
The third antenna has a null point on the first surface side of the substrate, and the directivity distribution is adjusted by the adjustment circuit so as to have a peak on the second surface side. The wireless communication device according to appendix 1, wherein the directivity is adjusted so as to face the second surface side of the substrate.
(Appendix 3)
The adjustment circuit has an inductor,
In the second antenna, the impedance is adjusted by the inductor, so that the frequency of the harmonic of the resonance frequency of the second antenna is reduced to be equal to the frequency of the third antenna. The radio communication device according to appendix 1 or 2, which resonates with an antenna.
(Appendix 4)
4. The wireless communication device according to any one of appendices 1 to 3, wherein the second antenna and the third antenna have sections arranged in parallel at a predetermined interval.
(Appendix 5)
5. The wireless communication device according to any one of appendices 1 to 4, wherein the first antenna and the second antenna construct a MIMO antenna when performing data communication.
(Appendix 6)
6. The wireless communication device according to any one of appendices 1 to 5, wherein the third antenna is a wireless LAN antenna.
(Appendix 7)
A wireless communication device,
A substrate having a first surface facing the human body when the wireless communication device makes a voice call, and a second surface opposite to the first surface;
A first antenna arranged on the substrate and used for data communication;
A second antenna arranged near the first antenna and used for data communication by a communication method different from that of the first antenna;
A switch having a first terminal connected to a feeding point of the first antenna, and a second terminal and a third terminal switchably connected to the first terminal;
A matching circuit connected to the second terminal, wherein when the switch connects the first terminal and the second terminal when the first antenna performs data communication, the resonance frequency of the first antenna is changed. A matching circuit for setting a resonance frequency different from the resonance frequency of the second antenna;
In the adjustment circuit connected to the third terminal, when the switch connects the first terminal and the third terminal when the second antenna performs data communication, the resonance frequency of the first antenna is changed. An adjustment circuit that adjusts the resonance frequency of the second antenna to be equal to the resonance frequency of the second antenna, and adjusts the directivity of the first antenna and the second antenna so as to face the second surface side of the substrate. Communication device.

DESCRIPTION OF SYMBOLS 10 Electronic equipment 50 Board 51 Ground plane 100 Wireless communication device 110 Main antenna 111 Feeding part 112 Branching parts 113, 114 End part 120 Sub-antenna 121 Feeding part 122 Branching part 123, 124 End part 130 WLAN antenna 131 Feeding part 132 Bending part 133 End 140 Switch 141, 142, 143 Terminal 150 Matching circuit 160 Adjustment circuit 170 Control unit 180 Matching circuit

Claims (6)

A wireless communication device,
A substrate having a first surface facing the human body when the wireless communication device makes a voice call, and a second surface opposite to the first surface;
A first antenna disposed on the first end side of the substrate and used for either voice communication or data communication;
A second antenna disposed on the second end side of the substrate opposite to the first end and used for data communication;
A third antenna arranged near the second antenna and used for data communication by a communication method different from that of the second antenna;
A switch having a first terminal connected to a feeding point of the second antenna, and a second terminal and a third terminal switchably connected to the first terminal;
A matching circuit connected to the second terminal, wherein when the switch connects the first terminal and the second terminal when the second antenna performs data communication, the resonance frequency of the second antenna is changed. A matching circuit for setting a resonance frequency different from the resonance frequency of the third antenna;
An adjusting circuit connected to the third terminal, wherein when the switch connects the first terminal and the third terminal when the third antenna performs data communication, the second antenna operates as the third terminal. An adjustment circuit that adjusts the impedance of the second antenna so as to resonate with the antenna and adjusts the directivity of the third antenna so as to face the second surface side of the substrate.   The third antenna has the null point on the first surface side of the substrate, and the directivity distribution is adjusted by the adjustment circuit so as to have a peak on the second surface side. The wireless communication device according to claim 1, wherein the directivity is adjusted so as to face the second surface side of the substrate. The adjustment circuit has an inductor,
When the impedance of the second antenna is adjusted by the inductor, the frequency of the harmonic of the resonance frequency of the second antenna is reduced to be equal to the frequency of the third antenna, and thus the third antenna is The wireless communication device according to claim 1, which resonates with an antenna.   The wireless communication device according to claim 1, wherein the second antenna and the third antenna have sections arranged in parallel at a predetermined interval.   The wireless communication device according to claim 1, wherein the first antenna and the second antenna construct a MIMO antenna when performing data communication.   The wireless communication device according to claim 1, wherein the third antenna is a wireless LAN antenna.

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