JP2008193286A - Mobile radio terminal and antenna matching circuit used for the mobile radio terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile radio terminal which has reduced reception interference due to mutual modulation among a plurality of antenna matching circuits. <P>SOLUTION: Since a diode switch 29 is set to a first frequency band (800 MHz band) generated by inputting a first radio wave and a third radio wave via a sub-antenna 23 and to an inter-terminal capacity (for example, 0.3 pF or less) where an identical frequency band spurious does not give reception interference to a main antenna 22 when the first radio wave is received by the main antenna 22, the third radio wave is emitted or received by a wireless LAN antenna 24, and the diode switch 29 is tuned off, reception is performed smoothly without being interfered by a spurious of the identical frequency band 800 MHz even if the level of a reception signal in the 800 MHz band is low. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a portable radio terminal and an antenna matching circuit used for the portable radio terminal, and particularly suitable for application when it is necessary to reduce reception interference due to intermodulation between a plurality of antenna matching circuits. The present invention relates to a radio terminal and an antenna matching circuit used for the portable radio terminal.

  In a portable wireless terminal such as a cellular phone, when only one antenna is provided, depending on the environment used, the propagation path is affected by the reflection, diffraction, scattering, etc. of the topography and buildings, and the propagation path is a multiple propagation path Thus, the transmission / reception state may be deteriorated. For this reason, an ordinary portable wireless terminal is often provided with two or more antennas and used in a state where an antenna having a good transmission / reception state is selected. In recent years, a wireless LAN antenna connected to a wireless LAN (local area network) for transmission / reception has been manufactured.

  Conventionally, this type of portable wireless terminal is a cellular phone 1 as shown in FIG. 3, for example, and includes a main antenna 2, a sub-antenna 3, a wireless LAN antenna 4, a matching circuit 5, and a matching circuit 6. A diode switch 7, a matching circuit 8, a diode switch 9, a matching circuit 10, a wireless LAN transmission / reception unit 11, a selection circuit 12, a transmission / reception unit 13, and a control unit 14. . In the cellular phone 1, there are two paths through which a transmission signal from the transmission / reception unit 13 is output to the outside, and the path is switched by the selection circuit 12. In this case, for example, when the transmission / reception state of the main antenna 2 is better than that of the sub-antenna 3, transmission / reception is performed with the main antenna 2 selected by the selection circuit 12 based on the control signal cta from the control unit 14. .

Further, the main antenna 2 emits or receives the first radio wave in the first frequency band (800 MHz band) and the second radio wave in the second frequency band (2.0 GHz band). In this case, the diode switch 7 is turned on based on the control signal ctb from the control unit 14, and the matching circuit 5, 6, 8 supports the frequency band of 800 MHz band between the transmission / reception unit 13 and the main antenna 2. Thus, the impedance is matched or the diode switch 7 is turned off based on the control signal ctb, and the matching circuits 5 and 6 cause the frequency in the 2.0 GHz band between the transmitting / receiving unit 13 and the main antenna 2. The impedance is matched corresponding to the band.
When the sub-antenna 3 is selected by the selection circuit 12, the first radio wave (800 MHz band) is radiated or received by the sub-antenna 3. In this case, the diode switch 9 is turned on based on the control signal ctc from the controller 14, and the matching circuit 10 causes the impedance between the transmitter / receiver 13 and the sub-antenna 3 to correspond to the frequency band of 800 MHz band. Be aligned. The third radio wave in the third frequency band (2.4 GHz band) used in the wireless LAN is radiated or received by the wireless LAN antenna 4.

  In the cellular phone 1, the diode switch 7 and the diode switch 9 may be simultaneously turned off, and the main antenna 2 may perform communication using radio waves in the first frequency band (800 MHz band). The diode switches 7 and 9 are each composed of a PIN diode, and the inter-terminal capacitance in the OFF state is, for example, 0.5 pF. At present, there is no appropriate prior art document information related to the above-described conventional technology.

However, the above conventional mobile phone has the following problems.
That is, in the mobile phone 1 of FIG. 3, when the diode switch 7 is in the on state and the diode switch 9 is in the off state, that is, when communication (transmission / reception) by radio waves in the 800 MHz band is performed by the main antenna 2, the 800 MHz A band radio wave is received by the sub-antenna 3 and input to the diode switch 9 in the off state. On the other hand, a 2.4 GHz band radio wave is also received by the sub-antenna 3 from the wireless LAN antenna 4 and input to the diode switch 9 in the off state. At this time, a 800 MHz band (= 2.4 GHz-800 MHz × 2) band spurious is generated by the diode switch 9, and this spurious signal is received by the main antenna 2 that is transmitting / receiving an 800 MHz band radio wave. This spurious is caused by mutual modulation between the 2.4 GHz band and 800 MHz band signals input to the diode switch 9 or harmonics generated by the nonlinearity of the leakage current of the diode switch 9. It is generated by. For this reason, as shown in FIG. 4, when the level of the received signal rs in the 800 MHz band is low, there is a problem that the reception sensitivity is lowered or reception becomes impossible due to interference with the 800 MHz band spurious sp of the same frequency band. is there.

  Similarly, when the diode switch 9 is in the on state and the diode switch 7 is in the off state, that is, when communication (transmission / reception) is performed by the sub antenna 3 using the 800 MHz band radio wave, the 800 MHz band radio wave is transmitted to the main antenna 2. And is input to the diode switch 7 in the off state. On the other hand, a 2.4 GHz band radio wave is also received by the main antenna 2 from the wireless LAN antenna 4 and input to the diode switch 7 in the off state. At this time, an 800 MHz band (= 2.4 GHz-800 MHz × 2) band spurious is generated by the diode switch 7, and this spurious wave is received by the sub-antenna 3 that is transmitting / receiving an 800 MHz band radio wave. This spurious is caused by mutual modulation between the 2.4 GHz band and 800 MHz band signals input to the diode switch 7 or harmonics generated by the nonlinearity of the leakage current of the diode switch 7. It is generated by. For this reason, there is a problem similar to the above.

  When the diode switch 7 and the diode switch 9 are simultaneously turned off and the main antenna 2 performs communication using radio waves in the first frequency band (800 MHz band), the diode switch 7 uses the 800 MHz band spurious. This spurious signal is received by the main antenna 2 and input to the diode switch 7 in the off state, which may cause the same problem as described above.

  The present invention has been made in view of the above circumstances, and provides a portable wireless terminal in which reception interference due to intermodulation between a plurality of antenna matching circuits is reduced, and an antenna matching circuit used in the portable wireless terminal. It is an object.

  In order to solve the above-mentioned problem, the invention according to claim 1 includes a first antenna for radiating or receiving a first radio wave in a first frequency band and a second radio wave in a second frequency band; A portable wireless terminal having a second antenna for radiating or receiving the first radio wave, a third antenna for radiating or receiving a third radio wave in a third frequency band, and a transceiver unit In particular, a first matching circuit for matching impedance between the transmission / reception unit and the first antenna corresponding to the first frequency band and the second frequency band, the transmission / reception unit, and the second antenna. And a second matching circuit that matches the impedance corresponding to the first frequency band, and the first matching circuit is turned on / off based on a first control signal. The impedance of the first matching circuit is controlled A first diode switch that is switched and set corresponding to a first frequency band or a second frequency band, and the second matching circuit is on / off controlled based on a second control signal; A second diode switch that sets an impedance of the second matching circuit corresponding to the first frequency band when the switch is on; the first diode switch includes the first frequency switch; The first diode switch having a first inter-terminal capacitance at which a first spurious signal having the same frequency band as the band does not interfere with reception of the first antenna and the second antenna; Is characterized in that the second spurious signal in the same frequency band as the first frequency band has a second inter-terminal capacitance that is at a level that does not cause reception interference to the first antenna.

  A second aspect of the present invention relates to the portable wireless terminal according to the first aspect, wherein the first inter-terminal capacitance of the first diode switch is such that the first radio wave is received by the second antenna. And when the third antenna radiates or receives the third radio wave and the first diode switch is in an OFF state, the first radio wave and the third radio wave are transmitted to the first antenna. The first spurious generated by the input through the first antenna and the second antenna have a value that does not interfere with reception of the first antenna and the second antenna, and the second diode switch The second inter-terminal capacitance is such that the first antenna receives the first radio wave and the third antenna radiates or receives the third radio wave, and the second diode switch off A level at which the second spurious generated when the first radio wave and the third radio wave are input via the second antenna does not interfere with reception of the first antenna. It has the value which becomes.

  A third aspect of the present invention relates to the portable wireless terminal according to the first or second aspect, wherein each of the first and second diode switches is composed of a PIN diode.

  According to a fourth aspect of the present invention, there is provided the portable wireless terminal according to the first, second, or third aspect, wherein the first and second spurious frequencies are 2 to the first frequency band from the third frequency band. It has a difference value obtained by subtracting double.

  A fifth aspect of the present invention relates to the portable radio terminal according to the first, second, third, or fourth aspect, wherein the first frequency band is an 800 MHz band, the second frequency band is a 2.0 GHz band, and the first frequency band. The third frequency band is set to the 2.4 GHz band.

  A sixth aspect of the present invention relates to the portable wireless terminal according to the first, second, third, fourth, or fifth aspect, wherein the capacitance between the first and second terminals is as close to zero as possible from 0.3 pF or less. It is characterized by being set to.

  The invention according to claim 7 is the first antenna for radiating or receiving the first radio wave in the first frequency band and the second radio wave in the second frequency band, and radiating the first radio wave or The present invention relates to an antenna matching circuit used in a portable wireless terminal having a second antenna for receiving, a third antenna for radiating or receiving a third radio wave in a third frequency band, and a transmission / reception unit, A first matching circuit for matching impedance between the transmission / reception unit and the first antenna corresponding to the first frequency band and the second frequency band; and the transmission / reception unit and the second antenna. And a second matching circuit for matching the impedance corresponding to the first frequency band, and the first matching circuit is controlled to be turned on / off based on the first control signal. The impedance of the first matching circuit A first diode switch that is switched and set corresponding to the first frequency band or the second frequency band, and the second matching circuit is controlled to be turned on / off based on a second control signal; And a second diode switch that sets an impedance of the second matching circuit corresponding to the first frequency band when in the ON state, and the first diode switch includes the first diode switch A first inter-terminal capacitance at which a first spurious signal in the same frequency band as the frequency band does not interfere with reception of the first antenna and the second antenna; The switch is characterized by having a second inter-terminal capacitance at which a second spurious signal in the same frequency band as the first frequency band has a level that does not interfere with reception of the first antenna.

  The invention according to claim 8 relates to the antenna matching circuit according to claim 7, wherein the first inter-terminal capacitance of the first diode switch is such that the first radio wave is received by the second antenna. And when the third antenna radiates or receives the third radio wave and the first diode switch is in an OFF state, the first radio wave and the third radio wave are transmitted to the first antenna. The first spurious generated by the input through the first antenna and the second antenna have a value that does not interfere with reception of the first antenna and the second antenna, and the second diode switch The second inter-terminal capacitance is such that the first antenna receives the first radio wave and the third antenna radiates or receives the third radio wave, and the second diode switch A level at which the second spurious generated when the first radio wave and the third radio wave are input via the second antenna does not interfere with the reception of the first antenna in the F state. It has the value which becomes.

  A ninth aspect of the present invention relates to the antenna matching circuit according to the seventh or eighth aspect, wherein each of the first and second diode switches is composed of a PIN diode.

  A tenth aspect of the present invention relates to the antenna matching circuit according to the seventh, eighth, or ninth aspect, wherein the frequency of the first and second spurious frequencies is 2 from the third frequency band to the first frequency band. It has a difference value obtained by subtracting double.

  The invention according to claim 11 relates to the antenna matching circuit according to claim 7, 8, 9 or 10, wherein the first frequency band is 800 MHz band, the second frequency band is 2.0 GHz band, and the first frequency band. The third frequency band is set to the 2.4 GHz band.

  A twelfth aspect of the invention relates to the antenna matching circuit according to the seventh, eighth, ninth, tenth, or eleventh aspect of the invention, wherein the capacitance between the first and second terminals is as close to zero as possible from 0.3 pF or less. It is characterized by being set to.

  According to the configuration of the present invention, the first diode switch receives the first radio wave by the second antenna and radiates or receives the third radio wave by the third antenna, and the first diode switch When the diode switch is in the OFF state, the first spurious signal in the same frequency band as the first frequency band generated by inputting the first radio wave and the third radio wave via the first antenna is the first spurious. Since the first terminal and the second antenna have a first inter-terminal capacitance that does not interfere with reception with respect to the first antenna and the second antenna, the first antenna and the second antenna receive the first radio wave reception signal. Even when the level is low, reception can be performed smoothly without being disturbed by the first spurious.

  The second diode switch receives the first radio wave from the first antenna and radiates or receives the third radio wave from the third antenna, and the second diode switch is in the off state. In this case, the second spurious signal having the same frequency band as the first frequency band generated when the first radio wave and the third radio wave are input via the second antenna is applied to the first antenna. Since the second inter-terminal capacitance has a level that does not cause reception interference, the first antenna is not disturbed by the second spurious even when the level of the reception signal of the first radio wave is low. , Reception can be performed smoothly.

  A portable radio terminal using a PIN diode having a pin-to-terminal capacitance that lowers the level of spurious due to internal intermodulation as a diode switch that switches the matching state of impedance between the transceiver and the antenna according to the frequency Provided is an antenna matching circuit used in the above.

FIG. 1 is a block diagram showing an electrical configuration of a main part of a portable radio terminal which is an embodiment of the present invention.
As shown in the figure, the mobile wireless terminal of this example is a mobile phone 21, which is a main antenna 22, a sub-antenna 23, a wireless LAN antenna 24, a matching circuit 25, a matching circuit 26, a diode The switch 27, the matching circuit 28, the diode switch 29, the matching circuit 30, the wireless LAN transmission / reception unit 31, the selection circuit 32, the transmission / reception unit 33, and the control unit 34 are included. The main antenna 22 radiates or receives a first radio wave in the first frequency band (800 MHz band) and a second radio wave in the second frequency band (2.0 GHz band). The sub-antenna 23 radiates or receives the first radio wave in the first frequency band (800 MHz band). The wireless LAN antenna 24 radiates or receives a third radio wave in the third frequency band (2.4 GHz band) used in the wireless LAN.

  The diode switch 27 is composed of a PIN diode, and is turned on / off by applying a bias voltage based on a control signal ctb from the control unit 34. In particular, in this embodiment, the diode switch 27 receives the first radio wave at the sub-antenna 23 and radiates or receives the third radio wave at the wireless LAN antenna 24, and the diode switch 27 is turned off. In the state, spurious signals in the same frequency band as the first frequency band (800 MHz band) generated by inputting the first radio wave and the third radio wave via the main antenna 22 are the main antenna 22 and the sub-antenna 23. Is set to a capacitance between terminals (for example, 0.3 pF or less to zero as much as possible), which is at a level that hardly causes reception interference, and off isolation (the signal from the input side to the output side in the off state) The amount of leakage current) has been improved.

  The inter-terminal capacitance is proportional to the junction area of the semiconductor constituting the PIN diode, and the leakage current is proportional to the inter-terminal capacitance. Since the non-linear portion of the leakage current causes spurious generation, the spurious level decreases as the inter-terminal capacitance of the PIN diode decreases. The spurious frequency has a difference value obtained by subtracting twice the first frequency band (800 M) from the third frequency band (2.4 GHz band). The matching circuits 25, 26, and 28 are composed of passive elements such as coils and capacitors, and correspond to a frequency in the 800 MHz band between the transmission / reception unit 33 and the main antenna 22 when the diode switch 27 is turned on. When the diode switch 27 is turned off, the matching circuits 25 and 26 correspond to the frequency in the 2.0 GHz band between the transmitter / receiver 33 and the main antenna 22. Match impedance.

  The diode switch 29 is composed of a PIN diode and is ON / OFF controlled based on a control signal ctc from the control unit 34. In particular, in this embodiment, the diode switch 29 receives the first radio wave at the main antenna 22 and radiates or receives the third radio wave at the wireless LAN antenna 24, and the diode switch 29 is turned off. In the state, the main antenna 22 receives spurious signals in the same frequency band as the first frequency band (800 MHz band) generated by inputting the first radio wave and the third radio wave via the sub-antenna 23. Capacitance between terminals at a level that does not cause interference (for example, 0.3 pF or less to zero as much as possible), and off isolation (amount of signal leakage from the input side to the output side in the off state) It has been improved. The spurious frequency has a difference value obtained by subtracting twice the first frequency band (800 M) from the third frequency band (2.4 GHz band).

  When the diode switch 29 is turned on, the matching circuit 30 matches impedance between the transmission / reception unit 33 and the sub-antenna 23 corresponding to the frequency in the 800 MHz band. The wireless LAN transmission / reception unit 31 transmits / receives a signal corresponding to the wireless LAN via the wireless LAN antenna 24. The selection circuit 32 selects the main antenna 22 or the sub antenna 23 based on the control signal cta from the control unit 34. The transmission / reception unit 33 performs transmission / reception of radio waves corresponding to a mobile phone via the main antenna 22 or the sub-antenna 23. The control unit 34 controls the entire mobile phone 21.

FIG. 2 is a diagram showing a spectrum of radio waves transmitted and received by the mobile phone 21 of FIG.
With reference to this figure, operation | movement of the mobile telephone 21 of this example is demonstrated.
In the cellular phone 21, there are two paths through which a transmission signal from the transmission / reception unit 33 is output to the outside, and the path switching is performed by the selection circuit 32. In this case, for example, when the transmission / reception state of the main antenna 22 is better than that of the sub-antenna 23, transmission / reception is performed with the main antenna 22 selected by the selection circuit 32 based on the control signal cta from the control unit 34. . Further, the main antenna 22 emits or receives the first radio wave in the first frequency band (800 MHz band) and the second radio wave in the second frequency band (2.0 GHz band). In this case, the diode switch 27 is turned on based on the control signal ctb from the control unit 34, and the matching circuits 25, 26, and 28 correspond to the 800 MHz band frequency between the transmission / reception unit 33 and the main antenna 22. Thus, the impedance is matched or the diode switch 27 is turned off based on the control signal ctb, and the matching circuits 25 and 26 adjust the frequency to the 2.0 GHz band between the transmitting / receiving unit 33 and the main antenna 22. Correspondingly, the impedance is matched.

  When the sub-antenna 23 is selected by the selection circuit 32, the first radio wave (800 MHz band) is radiated or received by the sub-antenna 23. In this case, the diode switch 29 is turned on based on the control signal ctc from the control unit 34, and the matching circuit 30 matches the impedance between the transmission / reception unit 33 and the sub-antenna 23 corresponding to the frequency in the 800 MHz band. Is done. The wireless LAN antenna 24 radiates or receives the third radio wave in the third frequency band (2.4 GHz band) used in the wireless LAN.

  On the other hand, when the diode switch 27 is in the on state and the diode switch 29 is in the off state, that is, when the main antenna 22 is transmitting and receiving radio waves in the 800 MHz band, the 800 MHz band radio waves are received by the sub antenna 23. It is input to the diode switch 29 in the off state. On the other hand, a 2.4 GHz band radio wave is also received by the sub-antenna 23 from the wireless LAN antenna 24 and input to the diode switch 29 in the off state. At this time, 800 MHz (= 2.4 GHz-800 MHz × 2) band spurious is generated by the diode switch 29, but this spurious level is extremely low, and the 800 MHz band radio wave is received by the main antenna 22 that is transmitting and receiving. Almost no interference. For this reason, as shown in FIG. 2, even when the level of the reception signal rs in the 800 MHz band is low, reception is smoothly performed without being disturbed by the spurious sp in the 800 MHz band of the same frequency band.

  Further, when the diode switch 29 is in the on state and the diode switch 27 is in the off state, that is, when the sub antenna 23 is performing transmission / reception using the 800 MHz band radio wave, the 800 MHz band radio wave is received by the main antenna 22. It is input to the diode switch 27 in the off state. On the other hand, a 2.4 GHz band radio wave is also received by the main antenna 22 from the wireless LAN antenna 24 and input to the diode switch 27 in the off state. At this time, 800 MHz (= 2.4 GHz-800 MHz × 2) band spurious is generated by the diode switch 27, but the level of this spurious is extremely low, and the 800 MHz band radio wave is received by the sub-antenna 23 that is transmitting / receiving. Almost no interference. Therefore, similarly to the above, even when the level of the reception signal rs in the 800 MHz band is low, reception is smoothly performed without being disturbed by the spurious sp in the 800 MHz band of the same frequency band.

  When the diode switch 27 and the diode switch 29 are simultaneously turned off and the main antenna 22 performs communication using radio waves in the first frequency band (800 MHz band), the diode switch 27 uses the 800 MHz band spurious. The spurious signal is received by the main antenna 22 and input to the diode switch 27 in the off state. The level of the spurious signal is extremely low, and the spurious signal is transmitted to the main antenna 22 that is transmitting / receiving an 800 MHz band radio wave. Almost no interference with reception. Therefore, similarly to the above, even when the level of the reception signal rs in the 800 MHz band is low, reception is smoothly performed without being disturbed by the spurious sp in the 800 MHz band of the same frequency band.

  As described above, in this embodiment, the diode switch 27 receives the first radio wave by the sub-antenna 23 and radiates or receives the third radio wave by the wireless LAN antenna 24. When the first radio wave and the third radio wave are input via the main antenna 22, spurious signals having the same frequency band as the first frequency band (800 MHz band) are generated when the first radio wave and the third radio wave are input through the main antenna 22. And the sub-antenna 23 is set to a terminal-to-terminal capacity (for example, 0.3 pF or less) at a level that hardly causes reception interference, the main antenna 22 and the sub-antenna 23 receive the received signal rs in the 800 MHz band. Even when the level of the signal is low, the reception is not interrupted by the spurious sp of the 800 MHz band of the same frequency band. It can be carried out in.

  The diode switch 29 receives the first radio wave at the main antenna 22 and radiates or receives the third radio wave at the wireless LAN antenna 24, and the diode switch 29 is in the off state. Spurious signals in the same frequency band as the first frequency band (800 MHz band) generated by inputting the first radio wave and the third radio wave via the sub-antenna 23 hardly cause reception interference to the main antenna 22. Since the inter-terminal capacitance is set to a level (for example, 0.3 pF or less), even if the level of the received signal rs in the 800 MHz band is low, the main antenna 22 has a spurious sp in the same frequency band of 800 MHz. Reception can be performed smoothly without interference.

The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiment, and even if there is a design change without departing from the gist of the present invention, Included in the invention.
For example, the PIN diodes constituting the diode switches 27 and 29 are PIN diodes (capacitance between terminals: 0.5 pF) constituting the conventional diode switches 7 and 9 if there are no restrictions on the pattern and shape of the substrate to be mounted. Even if a plurality of (for example, two) are connected in series, the inter-terminal capacitance is apparently reduced, so that the same operation and effect as in the above embodiment can be obtained. The present invention can also be applied to a portable wireless terminal having a Bluetooth communication function that uses the same frequency band as the third frequency band (2.4 GHz band) used in the wireless LAN.

  The present invention can be applied to all portable radio terminals having a plurality of antenna matching circuits.

It is a block diagram which shows the electric constitution of the principal part of the portable radio | wireless terminal which is one Example of this invention. It is a figure which shows the spectrum of the electromagnetic wave transmitted / received by the mobile telephone 21 of FIG. It is a block diagram which shows the electric constitution of the principal part of the conventional mobile telephone. It is a figure explaining the state of reception disturbance by the spurious which generate | occur | produces in the mobile telephone of FIG.

Explanation of symbols

21 Mobile phone (mobile wireless terminal)
22 Main antenna (first antenna)
23 Sub-antenna (second antenna)
24 Wireless LAN antenna (third antenna)
25, 26, 28 Matching circuit (first matching circuit, part of antenna matching circuit)
30 matching circuit (second matching circuit, part of antenna matching circuit)
27 Diode switch (first diode switch, part of antenna matching circuit)
29 Diode switch (second diode switch, part of antenna matching circuit)
31 Wireless LAN transceiver (part of portable wireless terminal)
32 Selection circuit (part of portable wireless terminal)
33 Transmitter / receiver (part of portable wireless terminal)
34 Control unit (part of portable wireless terminal)

Claims (12)

A first antenna for radiating or receiving a first radio wave in a first frequency band and a second radio wave in a second frequency band; and a second antenna for radiating or receiving the first radio wave. A portable wireless terminal having a third antenna for radiating or receiving a third radio wave in the third frequency band, and a transceiver unit,
A first matching circuit for matching impedance between the transmitting / receiving unit and the first antenna in accordance with the first frequency band and the second frequency band;
A second matching circuit for matching impedance corresponding to the first frequency band between the transmitting / receiving unit and the second antenna is provided;
The first matching circuit includes:
A first diode switch which is on / off controlled based on a first control signal and switches and sets the impedance of the first matching circuit corresponding to the first frequency band or the second frequency band; Have
The second matching circuit includes:
A second diode switch that is on / off controlled based on a second control signal and that sets an impedance of the second matching circuit corresponding to the first frequency band in an on state;
The first diode switch is:
A first inter-terminal capacitance at which a first spurious in the same frequency band as the first frequency band is at a level that does not interfere with reception for the first antenna and the second antenna;
The second diode switch is
A portable wireless terminal characterized by having a second inter-terminal capacitance at which a second spurious signal in the same frequency band as the first frequency band has a level that does not interfere with reception of the first antenna. The first inter-terminal capacitance of the first diode switch is:
When the first radio wave is received by the second antenna and the third radio wave is radiated or received by the third antenna, and the first diode switch is in an OFF state, the first antenna The first spurious generated by the input of the first radio wave and the third radio wave via the first antenna is at a level that does not interfere with reception of the first antenna and the second antenna. Has a value,
The second inter-terminal capacitance of the second diode switch is
When the first radio wave is received by the first antenna and the third radio wave is radiated or received by the third antenna, and the second diode switch is in an off state, the first antenna The second spurious generated by the input of the third radio wave and the third radio wave via the second antenna has a value that does not interfere with reception of the first antenna. The portable wireless terminal according to claim 1. The first and second diode switches are:
3. The portable wireless terminal according to claim 1, wherein each of the portable wireless terminals is composed of a PIN diode. The frequency of the first and second spurious is:
The portable wireless terminal according to claim 1, 2 or 3, wherein the portable wireless terminal has a difference value obtained by subtracting twice the first frequency band from the third frequency band.   The first frequency band is set to an 800 MHz band, the second frequency band is set to a 2.0 GHz band, and the third frequency band is set to a 2.4 GHz band. The portable wireless terminal according to 3 or 4. The capacitance between the first and second terminals is
6. The portable wireless terminal according to claim 1, wherein the portable wireless terminal is set so as to approach zero as much as possible from 0.3 pF or less. A first antenna for radiating or receiving a first radio wave in a first frequency band and a second radio wave in a second frequency band, and a second antenna for radiating or receiving the first radio wave And an antenna matching circuit used in a portable wireless terminal having a third antenna for radiating or receiving a third radio wave in the third frequency band, and a transceiver unit,
A first matching circuit for matching impedance between the transmitting / receiving unit and the first antenna in accordance with the first frequency band and the second frequency band;
A second matching circuit for matching impedance corresponding to the first frequency band between the transmitting / receiving unit and the second antenna is provided;
The first matching circuit includes:
A first diode switch which is on / off controlled based on a first control signal and switches and sets the impedance of the first matching circuit corresponding to the first frequency band or the second frequency band; Have
The second matching circuit includes:
A second diode switch that is on / off controlled based on a second control signal and that sets an impedance of the second matching circuit corresponding to the first frequency band in an on state;
The first diode switch is:
A first inter-terminal capacitance at which a first spurious in the same frequency band as the first frequency band is at a level that does not cause reception interference to the first antenna and the second antenna;
The second diode switch is
2. An antenna matching circuit comprising: a second inter-terminal capacitance at which a second spurious signal in the same frequency band as the first frequency band has a level that does not interfere with reception of the first antenna. The first inter-terminal capacitance of the first diode switch is:
When the first radio wave is received by the second antenna and the third radio wave is radiated or received by the third antenna, and the first diode switch is in an OFF state, the first antenna The first spurious generated by the input of the first radio wave and the third radio wave via the first antenna is at a level that does not interfere with reception of the first antenna and the second antenna. Has a value,
The second inter-terminal capacitance of the second diode switch is
When the first radio wave is received by the first antenna and the third radio wave is radiated or received by the third antenna, and the second diode switch is in an off state, the first antenna The second spurious generated by the input of the third radio wave and the third radio wave via the second antenna has a value that does not interfere with reception of the first antenna. The antenna matching circuit according to claim 7. The first and second diode switches are:
9. The antenna matching circuit according to claim 7, wherein each of the antenna matching circuits is composed of a PIN diode. The frequency of the first and second spurious is:
10. The antenna matching circuit according to claim 7, wherein the antenna matching circuit has a difference value obtained by subtracting twice the first frequency band from the third frequency band.   The first frequency band is set to an 800 MHz band, the second frequency band is set to a 2.0 GHz band, and the third frequency band is set to a 2.4 GHz band. The antenna matching circuit according to 9 or 10. The capacitance between the first and second terminals is
12. The antenna matching circuit according to claim 7, wherein the antenna matching circuit is set so as to approach zero as much as possible from 0.3 pF or less.

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