JP2013214870A - Radio terminal, power transmission system and short range radio signal transmission/reception system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transmit/receive a radio signal by suppressing the deterioration of a gain when an external device contacts, irrespective of the number of radio signals to be transmitted/received.SOLUTION: A radio terminal 1 includes: a detector unit 8 for detecting whether or not the radio terminal 1 contacts to a charging stand 20; and when apart from the charging stand 20, a transmitter/receiver unit 30 that includes a first antenna 2 for performing first radio communication by resonating at a first antenna frequency, and a second antenna 32 that resonates at a second antenna frequency higher than the first antenna frequency. When apart from the charging stand 20, the transmitter/receiver unit 30 performs first radio communication using the first antenna, and when the detector unit 8 detects a contact to the charging stand 20, the transmitter/receiver unit 30 transmits/receives a first radio signal using the second antenna 32.

Description

  The present invention relates to a wireless terminal capable of wireless communication, a power transmission system, and a short-range wireless signal transmission / reception system.

  In recent years, various wireless terminals that exchange information by transmitting and receiving radio waves to and from an external device via an antenna such as a mobile phone terminal have been developed.

  When such a wireless terminal is placed on a metal plate, it is known that the antenna's gain decreases, that is, the antenna characteristics deteriorate, because the resonance frequency of the antenna shifts.

  For this reason, a structure in which a parasitic element is provided separately from the antenna to improve the gain of the antenna is known. However, the parasitic element is provided only for improving the gain of the antenna when the wireless terminal is placed on the metal plate, and there arises a problem that the cost increases and the mounting area increases.

  Therefore, Patent Document 1 discloses a wireless communication terminal in which an antenna provided for transmitting / receiving radio waves having a frequency different from that for a cellular phone functions as a parasitic element.

  Patent Document 1 discloses a first antenna element for transmitting / receiving an 800 MHz band radio wave for a mobile phone and a 2.4 GHz band or a 1.5 GHz band different from those for mobile phones such as Bluetooth, W-LAN, and GPS. There is disclosed a wireless communication terminal provided with a second antenna element for transmitting and receiving a radio wave.

  In the wireless communication terminal, when the wireless communication terminal is placed on the metal plate, the resonance frequency of the second antenna element is in an 800 Mz band that is the resonance frequency of the first antenna element. An antenna ground portion having reactance is connected to the second antenna element.

  Thus, when the wireless communication terminal is placed on the metal plate, the second antenna element acts as a wireless power feeding element of the first antenna element, and the gain of the first antenna element on the metal plate is increased. The decline is suppressed.

JP 2009-159227 A (published July 16, 2009)

  However, the wireless communication terminal of Patent Document 1 is premised on having a wireless system that performs communication in the 800 MHz band and a wireless system that performs communication in the 2.4 GHz band or 1.5 GHz band different from the 800 MHz band. For this reason, the radio terminal having one type of radio system such as the 800 Mz band cannot suppress the gain deterioration of the antenna when placed on the metal plate, which causes a problem of low versatility.

  The present invention has been made in order to solve the above-described problems, and its purpose is not to depend on the number of mounted wireless systems, but to suppress a gain deterioration when an external device comes into contact with the wireless signal. Is to send and receive.

  In order to solve the above problems, a wireless terminal according to the present invention is a wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device, and is in contact with the external device. A first detection unit that detects whether or not a wireless signal used for the wireless communication by resonating at a first frequency when separated from the external device, and the external device A transmitter / receiver having a second transmitter / receiver for transmitting and receiving the wireless signal by resonating at a second frequency higher than the first frequency when in contact with the transmitter / receiver, When the radio signal is transmitted / received by the first transmission / reception unit and the detection unit detects contact with the external device when separated from the external device, the transmission / reception unit transmits the radio signal by the second transmission / reception unit. Sending and receiving radio signals It is a symptom.

  According to the above configuration, when the transmitter / receiver is separated from the external device, the transmitter / receiver resonates at a first frequency to transmit / receive a wireless signal used for the wireless communication, and the external device A second transmitting / receiving unit that transmits and receives the wireless signal by resonating at a second frequency higher than the first frequency when in contact. When the transmission / reception unit is away from the external device, the first transmission / reception unit transmits and receives the wireless signal, and when the detection unit detects that the external device is in contact with the external device, the transmission / reception unit The second transmission / reception unit transmits and receives the wireless signal.

  Accordingly, it is possible to transmit and receive the wireless signal by the transmission / reception unit while suppressing gain deterioration due to the wireless terminal coming into contact with the external device and shifting the frequency of the transmission / reception unit. Moreover, according to the said structure, in order to suppress gain degradation, it is not necessary to provide another transmission / reception part for performing radio | wireless communication in a different frequency band from the said radio signal.

  As described above, according to the above configuration, it is possible to perform wireless communication while suppressing gain deterioration when the external device comes into contact without depending on the number of mounted wireless systems.

  In order to solve the above problems, a wireless terminal according to the present invention is a wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device, and is in contact with the external device. A detection unit for detecting whether or not the radio communication is performed, an antenna for performing the wireless communication, and a frequency control unit for correcting the frequency of the antenna. Then, the frequency control unit corrects the frequency characteristics of the antenna so as to be favorable in the frequency band used in the wireless communication. Thereby, without depending on the number of mounted wireless systems, it is possible to transmit and receive wireless signals while suppressing gain deterioration when an external device contacts.

  In addition, when the detection unit detects that the external device is separated from the external device, the transmission / reception unit preferably transmits and receives the wireless signal by the first transmission / reception unit.

  According to the above configuration, since the detection unit detects that the remote device has been separated from the external device, the transmission / reception unit transmits and receives the wireless signal at the first transmission / reception unit. It is possible to prevent the gain deterioration due to the shift of the frequency of the part.

  The first transmission / reception unit includes a first antenna, and the transmission / reception unit controls the switching of the switching unit and the switching unit that switches driving of the first and second transmission / reception units. It is preferable to include a frequency control unit that controls the resonating frequency. The said transmission / reception part can be comprised by the said structure.

The first antenna may resonate at the first frequency, and the second transmission / reception unit may include a second antenna that resonates at the second frequency. Alternatively, the second transmission / reception unit may include the first antenna and a matching circuit for causing the first antenna to resonate at the second frequency. Furthermore, the first transmission / reception unit may include a matching circuit for resonating the first antenna at the first frequency.

  With the above configuration, the first or second transmission / reception unit can transmit and receive the wireless signal.

  The first antenna is an inverted F antenna, and the inverted F antenna has an element portion and first and second ends for grounding the element portion at different positions, The first transmission / reception unit includes the element unit and the first end, and the second transmission / reception unit includes the element unit and the second end, and the switching unit. It is preferable to switch the electrical connection between the element portion and the first or second end portion.

  The second transmitting / receiving unit may include a driven element, and the switching unit may switch an electrical connection between the driven element and the matching circuit.

  Also with the above configuration, the wireless signal can be transmitted / received by the first or second transmission / reception unit.

  Further, the radio signal is composed of a plurality of different frequency bands, and the first or second transmission / reception unit resonates at the first or second frequency, and thereby the radio signal composed of the plurality of frequency bands is received. It is preferable to transmit and receive. As a result, high-speed and high-quality wireless communication can be performed.

  The wireless terminal of the present invention is a wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device, and detects whether or not the external device has been contacted And a first transmitting / receiving unit that transmits and receives a wireless signal used for the wireless communication by resonating at a first frequency when separated from the external device, and the first transmitting and receiving unit when in contact with the external device. A transmission / reception unit having a second transmission / reception unit that transmits and receives the wireless signal by resonating at a second frequency higher than the frequency of 1, when the transmission / reception unit is separated from the external device, When the first transmission / reception unit transmits / receives the wireless signal and the detection unit detects that the external device is in contact with the external device, the transmission / reception unit transmits / receives the wireless signal by the second transmission / reception unit.

  The wireless terminal of the present invention is a wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device, and detecting whether or not the external device is contacted , An antenna for performing the wireless communication, and a frequency control unit for correcting the frequency of the antenna. When the detection unit detects that it has contacted the external device, the frequency control unit The frequency characteristics of the antenna are adjusted so as to be good in the frequency band used in the wireless communication.

  Thus, there is an effect that it is possible to perform wireless communication while suppressing gain deterioration when the external device contacts without depending on the number of mounted wireless systems.

1 is a diagram schematically illustrating a configuration of a wireless transmission system having a wireless terminal according to an embodiment of the present invention. It is a figure showing the relationship between the frequency and return loss of the radio | wireless communication terminal of a prior art. It is a figure showing the relationship between the frequency and return loss of the radio | wireless terminal which concern on one Embodiment of this invention. It is a figure showing the flowchart at the time of performing the 1st radio | wireless communication of the radio | wireless terminal which concerns on one Embodiment of this invention. It is a figure showing the flowchart at the time of performing the 2nd radio | wireless communication of the radio | wireless terminal which concerns on one Embodiment of this invention. It is a figure showing the structure of the 1st modification of a transmission / reception part. It is a figure showing the structure of the 2nd modification of a transmission / reception part. It is a figure showing the example of the structure of the 2nd modification of a transmission / reception part. It is a figure showing the structure of the 3rd modification of a transmission / reception part. It is a figure showing the structure of the 4th modification of a transmission / reception part. It is a figure showing the structure of an example of the termination | terminus part of FIG. 1 is a diagram schematically illustrating a configuration of a short-range wireless system including a wireless terminal according to an embodiment of the present invention. It is a figure showing the flowchart at the time of performing the 1st radio | wireless communication of the radio | wireless terminal which concerns on one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail.

(Configuration of wireless terminal)
First, the configuration of the wireless terminal 1 according to an embodiment of the present invention will be described using FIG.

  FIG. 1 is a diagram schematically illustrating a configuration of a wireless transmission system having a wireless terminal 1 of the present embodiment.

  As shown in FIG. 1, the wireless terminal 1 includes a transmission / reception unit (antenna) 30, a third antenna 4, a wireless circuit 5, a control circuit 6, a charging device unit 7, a detection unit 8, and main control. Part 10. The transmission / reception unit 30 includes a first antenna (first transmission / reception unit) 2, a radio circuit 3, a second antenna (second transmission / reception unit) 32, and a SW (switch; switching unit) 33. ing.

  The charging stand 20 includes a charging device unit 21, a control circuit 22, and a charging processing unit 23.

  A wireless transmission system (power transmission system) 9 is configured by the wireless terminal 1 and the charging stand 20.

  The wireless terminal 1 performs charging as a predetermined operation by contacting the charging stand (external device) 30. That is, the wireless terminal 1 is a non-contact wireless terminal that can be charged by receiving power from the charging stand 20 by being placed on the charging stand 20.

  In other words, the wireless terminal 1 can be expressed as a non-fixed type terminal that can be charged without being fixed to the charging stand 20 or the like when being charged. Note that the wireless terminal 1 may be able to be charged by being supplied with electric power from the charging stand 30 even if it is not in complete contact with the charging stand 30.

  Further, the wireless terminal 1 may be configured to be provided with a terminal for connecting a cable such as a USB cable, and can be charged via a cable connected to the terminal. That is, the wireless terminal 1 may be connected or fixed.

The wireless terminal 1 is, for example, a mobile terminal such as a mobile phone terminal, a mobile information terminal, or a smartphone. However, the wireless terminal 1 is not limited to these.

  The wireless terminal 1 is a terminal that can perform first wireless communication (wireless communication) and can also perform second wireless communication that is different from the first wireless communication in a frequency band used for communication.

  In the first wireless communication, the transmission / reception unit 30 transmits and receives wireless signals. That is, the transmission / reception unit 30 is a first wireless system for performing first wireless communication.

  In the second wireless communication, wireless signals are transmitted and received by the third antenna 4 and the wireless circuit 5. That is, the third antenna 4 and the wireless circuit 5 are a second wireless system for performing second wireless communication.

  For example, the first wireless communication is a wireless communication for calling a mobile phone or sending / receiving mail. Specifically, for example, the wireless terminal 1 performs the first wireless communication using the W-CDMA system. As a result, high-speed and high-quality wireless communication can be performed.

  On the other hand, the second wireless communication is a wireless communication for communication different from a mobile phone call, mail transmission / reception, and the like. Specifically, the wireless terminal 1 is, for example, a wireless terminal capable of performing second wireless communication using a 2.4 GHz band or 1.5 GHz band radio wave for Bluetooth, W-LAN, GPS, or the like. Suppose that

  Note that the wireless terminal 1 does not necessarily need to be able to use both the first and second wireless communications, and may be at least a terminal capable of performing the first wireless communication.

  In this embodiment, it is assumed that the frequency bands of radio waves used in the W-CDMA communication system used as the first wireless communication are band 1 (2100 MHz band) and band 6 (800 MHz band). As a result, the wireless terminal 1 realizes high-speed and high-quality first wireless communication.

  In the following description, the band 1 and the band 6 that are frequency bands used for the first wireless communication may be collectively referred to as a frequency band for the first wireless communication.

  As an example, the frequency band of the band 1 for signal transmission from the wireless terminal 1 is 1920 MHz to 1980 MHz, and the frequency band of the signal transmission band 6 is 830 MHz to 840 MHz. The frequency band of band 1 for signal reception to the wireless terminal 1 is 2110 MHz to 2170 MHz, and the frequency band of signal transmission for band 6 is 875 MHz to 885 MHz.

  Note that the frequency band used by the wireless terminal 1 in the W-CDMA system is not limited to band 1 (2100 MHz band) and band 6 (800 MHz band), and there is no particular limitation.

  The transmitting / receiving unit 30 transmits and receives a wireless signal used for the first wireless communication by resonating in a relatively low frequency band during normal time, that is, when the wireless terminal 1 is away from the charging stand 20. Antenna 2 and a second antenna 32 that resonates in a frequency band relatively higher than that of the first antenna 2.

  The first antenna 2 is an antenna for transmitting and receiving radio waves for the first wireless communication. The wireless circuit 3 is a first wireless circuit for wireless communication.

  The first antenna 2 transmits and receives a radio signal used for the first radio communication by resonating in a relatively lower frequency band than the second antenna 32. In the following description, in order to perform the first wireless communication, the frequency at which the first antenna 2 resonates is set to the resonance frequency (first frequency) of the first antenna or the frequency of the first antenna ( May be referred to as a first frequency).

  The first antenna 2 is adjusted so that when the wireless terminal 1 is away from the charging stand 20, the antenna characteristics are good in the frequency bands of band 1 and band 6 of W-CDMA. Yes. The first antenna 2 is, for example, in a normal state in which the wireless terminal 1 is not placed on the charging base 20 so that radio waves can be transmitted and received by the W-CDMA system, and in the band 1 and band 6 frequency bands. 1 antenna 2 is designed to have good performance.

  The second antenna 32 transmits and receives a radio signal used for the first radio communication by resonating in a higher frequency band than the first antenna 2. In the following description, in order to perform the first wireless communication, the frequency at which the second antenna 32 resonates is set to the resonance frequency of the second antenna (second frequency) or the frequency of the second antenna ( (Second frequency).

  The second antenna 32 is connected to the wireless circuit 3 via the SW 33.

  When the wireless terminal 1 is in contact with the charging stand 20, the second antenna 32 is adjusted so that the second antenna 32 has good antenna characteristics in the band 1 and band 6 frequency bands.

  In a normal state where the wireless terminal 1 is not placed on the charging base 20, the second antenna 32 has good characteristics in a frequency band slightly higher than the frequency bands of band1 and band6, and the wireless terminal 1 is connected to the charging base. The second antenna 32 is designed to have good characteristics in the band 1 and band 6 frequency bands in the state where it is placed on the band 20.

  Alternatively, the second antenna 32 only needs to have good characteristics in the frequency bands of band1 and band6 when the wireless terminal 1 is placed on the charging base 20, and the second antenna 32 in the electric base 20 is sufficient. You may arrange | position in the radio | wireless terminal 1 which is hard to receive the influence of a metal and is hard to shift | deviate a frequency.

  When the wireless terminal 1 starts wireless transmission with the charging stand 20, the transceiver unit 30 connects the wireless circuit unit 3 and the second antenna 32 by the SW 33.

  The radio circuit 3 is connected to the first antenna 2 and the second antenna 32 via the SW 33 and also to the main control unit 10.

  The wireless circuit 3 transmits and receives radio waves in frequency bands such as band 1 and band 6 via the first antenna 2 or the second antenna 32 in order to perform the first wireless communication.

When the wireless terminal 1 is placed on the charging stand 20, the resonance frequencies of the first antenna 2 and the second antenna 32 deviate. The amount of deviation of the resonance frequency of the first antenna 2 is AMHz for both bands 1 and 6, and the amount of deviation of the resonance frequency of the second antenna 32 is BMHz for both band1 and band6. The first antenna is designed to be good in the band 1 and band 6 frequency bands, and the second antenna 32 is designed to be good in a frequency band higher by B MHz than the band 1 and band 6 frequency bands.

  Here, the amount of deviation of the resonance frequency of the second antenna 32 is described as BMHz for both band1 and band6, but when the amount of deviation of band1 and band6 is different, it resonates at a higher frequency according to the amount of deviation. Thus, it is necessary to design the second antenna 32.

  As an example, A MHz = 30 MHz and B MHz = 35 MHz.

  The SW 33 is a switch that switches the frequency at which the transmission / reception unit 30 resonates between the frequency of the first antenna and the frequency of the second antenna.

  The SW 33 connects the wireless circuit 3 to either the first antenna 2 or the second antenna 32 based on an instruction from the main control unit 10. The SW 33 connects the first antenna 2 and the wireless circuit 3 in a normal state where the wireless terminal 1 is away from the charging stand 20. On the other hand, the SW 33 connects the second antenna 32 and the wireless circuit 3 when the wireless terminal 1 is placed on the charging stand 20.

  The third antenna 4 is an antenna for transmitting and receiving radio waves for the second wireless communication. As an example, the third antenna 4 is designed to have a resonance frequency in the 2.4 GHz band or the 1.5 GHz band.

  The radio circuit 5 is connected to the third antenna 4 and is also connected to the main control unit 10.

  The wireless circuit 5 transmits and receives radio waves in a frequency band such as a 2.4 GHz band or a 1.5 GHz band via the third antenna 4 in order to perform the second wireless communication.

  In the following description, a frequency band such as a 2.4 GHz band or a 1.5 GHz band that is a frequency band used for the second wireless communication may be referred to as a second wireless communication frequency band.

  The main control unit 10 controls the overall driving of the wireless terminal 1. The main control unit 10 includes one or a plurality of CPUs.

  The main control unit 10 performs processing according to the contents of the first or second radio signal received by the first antenna 2, the second antenna 32, or the third antenna 4. The main control unit 10 also controls the charging stand 20. Details of the control of the charging stand 20 by the main control unit 10 will be described later. The main control unit 10 also detects whether or not the charging device unit 7 is in a chargeable state.

  The main control unit 10 includes a first radio control unit 11, a second radio control unit 12, a frequency control unit 13, and a detection control unit 14.

  The first radio control unit 11 controls the driving of the radio circuit 3. The first radio control unit 11 drives the radio circuit 3 in response to an input from the user, starts the first radio communication, or receives the signal via the first antenna 2 or the second antenna 32. When the first wireless signal is input from the wireless circuit 3, processing corresponding to the received first wireless signal is performed.

The second radio control unit 12 controls the driving of the radio circuit 5. The second radio control unit 12 drives the radio circuit 5 in response to an input from the user to start the second radio communication, or the second radio signal received via the third antenna 4 By receiving the input from the wireless circuit 5, processing corresponding to the received second wireless signal is executed.

  The frequency control unit 13 corrects the frequency at which the transmission / reception unit 30 resonates. When the detection unit 8 detects that the charging base 20 has been touched, the frequency control unit 13 adjusts the frequency characteristics of the transmission / reception unit 30 so as to be favorable in the frequency band for the first wireless communication.

  Specifically, when the wireless terminal 1 is away from the charging base 20, that is, when the detection unit 8 does not detect that the wireless terminal 1 is away from the charging base 20, the frequency control unit 13 The SW 2 is controlled so that the antenna 2 is electrically connected and the radio circuit 3 and the second antenna 32 are electrically disconnected. Thereby, the frequency control part 13 resonates the transmission / reception part 30 in the frequency band of a relatively low 1st antenna among the frequencies with which the transmission / reception part 30 resonates. As a result, the transmission / reception unit 30 has good antenna characteristics in the first wireless communication frequency band in a normal state where the transmission / reception unit 30 is not placed on the charging stand 20.

  On the other hand, when the wireless terminal 1 is placed on the charging stand 20, that is, when the detection unit 8 detects the charging stand 20, the frequency control unit 13 electrically connects the wireless circuit 3 and the first antenna 2. And the SW 33 is controlled so that the radio circuit 3 and the second antenna 32 are electrically connected. Thereby, the frequency control part 13 resonates the transmission / reception part 30 in the frequency band of a relatively high 2nd antenna among the frequencies in which the transmission / reception part 30 resonates. As a result, the transmission / reception unit 30 has good antenna characteristics in the first wireless communication frequency band even when placed on the charging stand 20.

  The detection control unit 14 controls driving of the detection unit 8. When the detection control unit 14 acquires information indicating that the charging stand 20 has been detected from the detection unit 8, the detection control unit 14 outputs the detection information to the frequency control unit 13.

  Further, when the detection control unit 14 acquires information indicating that the charging stand 20 is separated from the detection unit 8, the detection control unit 14 outputs undetected information to the frequency control unit 13.

  The charging device unit 7 is a mechanism for receiving non-contact power transmission from a charging device unit 21 described later, and includes, for example, a secondary coil for non-contact power transmission. Moreover, the charging device part 7 is provided with the battery 7a for charging the electric power transmitted by non-contact electric power. The charging device unit 7 controls driving of a charging device unit 21 and a control circuit 22 described later based on an instruction from the main control unit 10.

  The control circuit 6 is a control circuit that controls the power receiving operation and the charging operation of the charging device unit 7, and exchanges control signals with the control circuit 22.

  As an example, the charging device unit 7 and the control circuit 6 may be configured to be detachable as a battery pack.

  The detection unit 8 detects whether or not the wireless terminal 1 is placed on the charging stand 20 and whether or not the wireless terminal 1 is separated from the charging stand 20 after the charging stand 20 completes charging of the battery 7a. is there.

  For example, the detection unit 8 detects that the wireless terminal 1 is placed on the charging stand 20 by detecting that the charging to the battery 7 a is started by the charging stand 20. When detecting that charging of the battery 7 a by the charging base 20 has been started, the detection unit 8 outputs information indicating that the charging base 20 has been detected to the detection control unit 14.

  In addition, when the detection unit 8 detects that the wireless terminal 1 is separated from the charging stand 20, the detection unit 8 outputs information indicating that the charging stand 20 is separated to the detection control unit 14.

  The detection unit 8 only needs to detect that the battery 7a built in the wireless terminal 1 is charged by the charging base 20 and can detect that the wireless terminal 1 has moved from the charging base 20. There is no particular limitation. As an example, the detection unit 8 can be configured by any one or a plurality of sensors such as a proximity sensor, an acceleration sensor, and a coil detection sensor.

  When the various sensors constituting the detection unit 8 detect that the wireless terminal 1 is separated from the charging base 20, the SW 33 is switched to connect the first antenna 2 and the wireless circuit 3, and the frequency adjustment unit 31. Is disconnected from the electrical connection with the radio circuit 3.

  Here, generally, a charging path differs between a case where a battery built in a wireless terminal is charged by a charging stand and a method (contact type) in which charging is performed via a USB cable or the like. For this reason, even if the wireless terminal 1 has a configuration capable of being charged in a contact manner, the detection unit 8 is not charged in the contact manner with the battery 7a, but is charged with the battery 7a by the charging stand 20. Can be detected accurately.

  The charging stand 20 is a non-contact cradle. The charging stand 20 has a flat structure, for example, so that the wireless terminal 1 can be placed on the surface.

  The charging stand 20 is a charging stand capable of transmitting power to the wireless terminal 1 placed on the surface without contact. In other words, the charging stand 20 can also be expressed as a non-fixed charging stand that can charge the wireless terminal 1 without fixing the wireless terminal 1.

  For power transmission from the charging stand 20 to the wireless terminal 1, the charging device unit 21, the control circuit 22 and the charging processing unit 23 of the charging stand 20, and the charging device unit 7 and the control circuit 6 of the wireless terminal 1 cooperate. It is realized by.

  The charging device unit 21 is a mechanism for performing non-contact power transmission to the charging device unit 7, and includes, for example, a primary coil for non-contact power transmission.

  The control circuit 22 is a control circuit that controls the power transmission operation of the charging device unit 21, and exchanges control signals related to charging such as service information and timing information with the control circuit 6.

  The method of exchanging control signals between the control circuit 22 and the control circuit 6 is not particularly limited, and may be wired or wireless. For example, you may communicate wirelessly using the coil with which the charging device part 7 and the charging device part 21 are provided.

  The charging processing unit 23 controls operations of the charging device unit 21 and the control circuit 22 so that non-contact power transmission from the charging base 20 to the wireless terminal 1 is achieved.

  The contactless power transmission method used in the present embodiment is not particularly limited, and may be, for example, an electromagnetic induction method, a magnetic field resonance method, an electric field coupling method, a radio wave reception method, or the like.

  In addition, the structure of the charging device part 7 and the charging device part 21, and the structure of the control circuit 6 and the control circuit 22 can be suitably changed according to the system of non-contact electric power transmission to be used.

  For example, in the case of an electromagnetic induction method or a magnetic field resonance method, the charging device unit 21 may include a primary coil, and the charging device unit 7 may include a secondary coil. It is only necessary to have an electrode, and if it is a radio wave reception system, it is sufficient to have an antenna and a resonance circuit.

  Further, the third antenna 4, the wireless circuit 5, and the second wireless control unit 12 may be provided arbitrarily or may not be provided.

(Description of main effects of the wireless terminal 1)
Next, main effects of the wireless terminal 1 will be described with reference to FIGS. 2 and 3.

  FIG. 2 is a diagram illustrating the relationship between the frequency and the return loss of the wireless communication terminal disclosed in Patent Document 1 described above. FIG. 3 is a diagram illustrating the relationship between the frequency and return loss of radio terminal 1 according to the present embodiment.

  In general, a charging stand that charges a mobile terminal in a non-contact manner is used in an internal circuit, such as a matrix coil that detects the position of the mobile terminal, as compared with a charging device that charges a mobile terminal in a contact manner. Many metal parts are used.

  For this reason, when the wireless communication terminal of Patent Document 1 or the wireless terminal 1 is placed on the charging stand, the frequency of the antenna is shifted from the frequency band used for communication as shown in FIGS. 2 and 3. The performance of the antenna in the band deteriorates.

  2 and 3, the horizontal axis represents frequency (MHz) and the vertical axis represents return loss (dB).

  In FIG. 2, a graph g1 represents a return loss of the wireless communication terminal of Patent Document 1 at a normal time not placed on the charging stand, and a graph g2 represents the wireless communication of Patent Literature 1 placed on the charging stand. This represents the return loss of the terminal.

  In FIG. 3, the graph G <b> 1 represents the return loss of the wireless terminal 1 at the normal time not placed on the charging stand 20, and the graph G <b> 2 represents the return of the first antenna 2 when placed on the charging stand 20. The graph G3 represents the return loss of the second antenna 32 in a state where it is placed on the charging stand 20.

  As shown in FIG. 2, in the graph g1, the antenna resonates in each band 1 and band 6, and the antenna characteristics are good. On the other hand, in the graph g2, the return loss of the antenna is obtained in the band 1 and the characteristic deterioration can be suppressed. However, in the band 6 the return loss is not taken at all and the antenna is hardly radiated. Recognize. Depending on the design of the mobile communication terminal, it is possible to suppress the deterioration of the antenna characteristics of band 6, but conversely, good antenna characteristics cannot be obtained in the band of band 1.

  Thus, according to the wireless communication terminal of Patent Document 1, it can be understood that gain deterioration of one band can be suppressed, but gain deterioration cannot be suppressed by a plurality of bands.

  This is because there is only one parasitic element used in Patent Document 1, and basically only one resonance can be obtained from one parasitic element. In addition, since the parasitic element is used as an antenna of another system, problems such as mutual interference with each other's antenna also occur.

  On the other hand, in the wireless terminal 1 of the present embodiment, as shown in FIG. 3, the graph G2 has gain degradation in both band1 and band6, but in the graphs G1 and G3, both band1 and band6 have both. It can be seen that a good gain is obtained.

  When the wireless terminal 1 is placed on the charging stand 20, the wireless circuit 3 is connected to the second antenna 32 by the SW 33, and the return loss of the antenna at that time is a graph G3.

  Thus, in the wireless terminal 1, when wireless communication is performed using the band 1 and the band 6 when placed on the charging stand 20, the wireless communication is performed while preventing gain deterioration by using the second antenna 32. I can see that

  As described above, in the present embodiment, the second antenna 32 is good at a frequency (first frequency band for wireless communication) used for communication when the wireless terminal 1 is placed on the charging stand 20. By adjusting the frequencies of the band1 and band6 antennas so as to obtain antenna characteristics, it is possible to suppress characteristic degradation in both frequency bands (band1 and band6) when placed on the charging stand 20.

  As described above, when the wireless terminal 1 is away from the charging base 20, the wireless terminal 1 resonates at the first antenna frequency, which is a relatively low frequency, so that the first wireless signal used for the first wireless communication is transmitted. A transmission / reception unit having a first antenna 2 that transmits and receives and a second antenna 32 that resonates at a frequency of a second antenna that is a relatively higher frequency than the first antenna 2 is provided.

  The transmitter / receiver 30 transmits and receives the first radio signal used for the first radio communication by the first antenna 2 when the radio terminal 1 is away from the charging stand 20. Further, when the detection unit 8 detects that the charging stand 20 and the wireless terminal 1 are in contact, the transmission / reception unit 30 transmits / receives the first wireless signal by the second antenna 32.

  Specifically, the transmission / reception unit 30 includes a first antenna 2 that resonates at the frequency of the first antenna, a second antenna 32 that resonates at the frequency of the second antenna, the first antenna 2 and the second antenna 2. SW33 for switching the driving of the antenna 32 and the frequency control unit 13 for controlling the frequency at which the transmitting / receiving unit 30 resonates by controlling the frequency of the first antenna and the frequency of the second antenna by controlling the switching of the SW33. And.

  Thus, when the detection unit 8 detects that the charging base 20 is in contact, the frequency control unit 13 switches the SW 33 so that the second antenna 32 and the radio circuit 3 are electrically connected. The frequency control unit 13 switches the antenna for performing the first wireless communication from the first antenna 2 to the second antenna 32. That is, the frequency control unit 13 switches the resonant frequency band of the transmission / reception unit 30 from the frequency of the first antenna to the frequency of the second antenna.

  Thereby, since the wireless terminal 1 is placed on the charging stand 20, it is possible to suppress the gain deterioration due to the frequency shift of the transmission / reception unit 30 and to perform the first wireless communication by the transmission / reception unit 30. .

  Moreover, according to the said structure, in order to suppress gain degradation, it is not necessary to provide the transmission / reception part for transmitting / receiving the radio signal of a frequency band different from a 1st radio signal. Thus, according to the said structure, without depending on the number of the radio | wireless systems which communicate, the 1st radio | wireless communication is possible, suppressing the gain degradation at the time of the charging stand 20 contacting.

  In addition, when the wireless terminal 1 detects that the detection unit 8 is separated from the charging base 20, the frequency control unit 13 switches the SW 33 so that the first antenna 2 and the wireless circuit 3 are electrically connected. That is, the transmission / reception unit 30 transmits / receives the first radio signal by the first antenna 2.

  According to the above configuration, after detecting that the detection unit 8 is away from the charging stand 20, the frequency control unit 13 determines the resonance frequency of the transmission / reception unit 30 from the frequency of the second antenna. Since the frequency is switched to the frequency, it is possible to reliably prevent the gain deterioration due to the shift of the frequency of the transmission / reception unit 30.

  The first radio signal is composed of band1 and band6, which are different frequency bands. The first antenna 2 has a resonance frequency number set so that the antenna characteristics are good in both the band 1 and the band 6 when the first antenna 2 is separated from the charging base 20 as the frequency of the first antenna. The second antenna 32 is set as a frequency of the second antenna so that the antenna characteristics are good in both band 1 and band 6 when in contact with the charging stand 20.

  Thereby, when the wireless terminal 1 is away from the charging stand, the first antenna 2 resonates at the frequency of the first antenna, thereby transmitting and receiving the first wireless signal composed of band1 and band6. In addition, when the wireless terminal 1 is in contact with the charging stand, the second antenna 32 resonates at the frequency of the second antenna, thereby transmitting and receiving the first wireless signal composed of band1 and band6. As a result, high-speed and high-quality wireless communication can be performed.

  The wireless terminal 1 can charge the battery 7a by the charging stand 20 for supplying electric power in a non-contact manner. Thereby, even if the wireless terminal 1 is placed on the charging stand 20 for a relatively long time to charge the battery 7a built in the wireless terminal 1, the gain deterioration of the wireless terminal 1 is suppressed. Thus, the first wireless communication can be performed.

  In addition, compared with the conventional antenna etc., the transmission / reception part 30 is the frequency band for 1st radio | wireless communication both in the case where it is separated from the charging stand 20, and the case where it is contacting compared with the conventional antenna. Therefore, it may be designed so as to have good antenna characteristics.

  Further, the wireless terminal 1 may be capable of charging the battery 7a in a contact manner, for example, by connecting a USB cable instead of the charging stand 20.

  Here, in general, a charging stand for charging a mobile terminal in a non-contact manner is used in an internal circuit such as a matrix coil for detecting the position of the mobile terminal as compared with a charging device for charging a mobile terminal in a contact type. Many used metal parts are used.

  For this reason, even in the wireless terminal 1, the effect of reducing the gain deterioration is greater when charging is performed using the non-contact charging base 20 than when charging is performed using the contact charging device.

(Processing flow of the wireless terminal 1)
Next, the process flow of the wireless terminal 1 will be described.

  FIG. 4 is a diagram illustrating a flowchart when the wireless terminal 1 performs the first wireless communication.

  In the initial state, the SW 33 is set so that the wireless circuit 3 and the first antenna 2 are electrically connected and the wireless circuit 3 and the second antenna 32 are not electrically connected.

  When the first wireless signal is transmitted, the first antenna 2 receives the transmitted first wireless signal (YES in step S11) and outputs the first wireless signal to the wireless circuit 3. The radio circuit 3 outputs information indicated by the first radio signal to the first radio control unit 11. Thereby, the first wireless control unit 11 executes processing corresponding to the first wireless signal acquired from the wireless circuit 3, such as executing various applications stored in a storage unit (not shown). Thus, the wireless terminal 1 performs the first wireless communication (step S12).

  Next, the wireless terminal 1 is placed on the charging stand 20 by the user. Then, the main control unit 10 drives the charging device unit 21, the control circuit 22, and the charging processing unit 23 via the control circuit 6 and the charging device unit 7, whereby charging from the charging stand 20 to the battery 7 a is started. The

  And the detection part 8 detects that the radio | wireless terminal 1 was mounted in the charging stand 20 by the charge from the charging stand 20 to the battery 7a being started (YES of step S13), and detected the charging stand 20. Information to that effect is output to the detection control unit 14.

  When the detection control unit 14 acquires information indicating that the charging base 20 has been detected from the detection unit 8, the detection control unit 14 outputs the detection information to the frequency control unit 13. And the frequency control part 13 will switch SW33 to the 2nd antenna 32 side, if detection information is acquired from the detection control part 14 (step S14). That is, when the frequency control unit 13 acquires the detection information from the detection control unit 14, the radio circuit 3 and the second antenna 32 are electrically connected, and the radio circuit 3 and the first antenna 2 are electrically connected. SW33 is switched so as to be shut off.

  When the first radio signal is transmitted, the second antenna 32 receives the transmitted first radio signal (YES in step S15) and outputs it to the radio circuit 3. The radio circuit 3 outputs information indicated by the first radio signal to the first radio control unit 11. Thereby, the wireless terminal 1 executes the first wireless communication by the first wireless control unit 11 executing the process according to the first wireless signal (step S16).

  Next, when charging is stopped, for example, charging from the charging stand 20 to the battery 7a is completed, the detection unit 8 detects whether or not the wireless terminal 1 is separated from the charging stand 20 (step S17).

  When the user moves the wireless terminal 1 away from the charging stand 20, the detection unit 8 detects that the wireless terminal 1 has left the charging stand 20 (YES in step S17), and information that the charging stand 20 has left. Is output to the detection control unit 14. When the detection control unit 14 acquires information indicating that the charging stand 20 is separated from the detection unit 8, the detection control unit 14 outputs undetected information to the frequency control unit 13.

  When acquiring the non-detection information from the detection control unit 14, the frequency control unit 13 switches the SW 33 to the first antenna 2 side (step S18). That is, when the frequency control unit 13 acquires the non-detection information from the detection control unit 14, the frequency control unit 13 electrically connects the radio circuit 3 and the first antenna 2, and the radio circuit 3 and the second antenna 32 are electrically connected. SW33 is switched so as to be interrupted.

  Next, the flow of processing when performing the second wireless communication will be described with reference to FIG. FIG. 5 is a diagram illustrating a flowchart when the wireless terminal 1 performs the second wireless communication.

When the second wireless signal is transmitted to the wireless terminal 1, the third antenna 4 receives the transmitted second wireless signal (YES in step S21) and outputs the second wireless signal to the wireless circuit 5. . The radio circuit 5 outputs information indicated by the second radio signal to the second radio control unit 12. Thereby, the second wireless control unit 12 executes processing corresponding to the second wireless signal acquired from the wireless circuit 5, such as executing various applications stored in a storage unit (not shown). Thus, the wireless terminal 1 executes the second wireless communication (step S22).

  The wireless terminal 1 performs the second wireless communication separately from the first antenna 2, the second antenna 32, the wireless circuit 3, and the first wireless control unit 11 for performing the first wireless communication. The third antenna 4, the radio circuit 5, and the second radio control unit 12 are provided, and can be individually driven and controlled.

  Therefore, the wireless terminal 1 can execute the second wireless communication at the same time as the first wireless communication.

  On the other hand, in the wireless communication terminal of Patent Document 1 described above, when using radio waves of two types of wavelengths, the second antenna element is caused to act as a wireless power feeding element in order to prevent gain reduction of the first antenna element. Therefore, when the first antenna element transmits / receives an 800 MHz band radio wave, the second antenna element cannot transmit / receive a 2.4 GHz band or 1.5 GHz band radio wave.

  Thus, since the wireless terminal 1 can simultaneously execute the first and second wireless communications, it is highly convenient.

  Further, in the process of step S17, even when the charging from the charging base 20 to the battery 7a is completed and the charging process is completed, the detection unit 8 detects that the wireless terminal 1 has left the charging base 20. Until the frequency control unit 13 is in a state where the wireless circuit 3 and the second antenna 32 are electrically connected to each other and the wireless circuit 3 and the first antenna 2 are electrically disconnected. Keep it as Therefore, even when the charging of the battery 7a is completed, it is possible to continue suppressing the gain deterioration of the wireless terminal 1 with respect to the first wireless signal.

(First modification of transmission / reception unit)
The transmission / reception unit 30 described with reference to FIG. 1 may have various other configurations. Hereinafter, modifications of the transmission / reception unit will be described.

  FIG. 6 is a diagram illustrating a configuration of a first modification of the transmission / reception unit 30.

  As shown in FIG. 6, in FIG. 6, the wireless terminal 1 includes a transmission / reception unit 40 instead of the transmission / reception unit 30.

  The transmission / reception unit 40 includes a first antenna 2, a radio circuit 3, a first matching circuit 43, a first SW (switching unit) 42, a second matching circuit 45, and a second SW (switching). Part) 44.

  The first antenna 2 and the first matching circuit 43 constitute a first transmission / reception unit 47. The first transmitting / receiving unit 48 is configured by the first antenna 2 and the second matching circuit 45.

  The first matching circuit 43 and the second matching circuit 45 are arranged in parallel. The first matching circuit 43 and the second matching circuit 45 each include a capacitor and reactance.

  The first antenna 2 is electrically connected to the first matching circuit 43 and thereby resonates at a relatively low frequency of the first antenna. Further, the first antenna 2 is electrically connected to the second matching circuit 45, and thus resonates at a relatively high frequency of the second antenna.

  The first matching circuit 42 is a matching circuit for causing the first antenna 2 to resonate at a frequency of the first antenna that is a relatively low frequency band.

The first matching circuit 42 is used when the wireless terminal 1 is not charged on the charging stand 20.
In the normal state where the wireless terminal 1 is not placed on the charging base 20, that is, in the state where the detection unit 8 does not detect the charging base 20, the first matching circuit 42 is connected to the band 1. And band 6 are configured by setting constants of capacitors and reactances so that good antenna characteristics can be obtained.

  The second matching circuit 45 is a matching circuit for causing the first antenna 2 to resonate at a frequency of the second antenna that is a relatively high frequency.

The second matching circuit 45 is used when the wireless terminal 1 is charged on the charging stand 20.
The second matching circuit 45 is configured such that when the wireless terminal 1 is placed on the charging stand 20 and in non-contact charging, that is, when the detection unit 8 detects the charging stand 20, the first antenna 2 is The constants of the capacitor and the reactance are set so that good antenna characteristics are obtained in both frequency bands of the band 6.

  The first SW 42 and the second SW 44 are switches that switch the frequency of the first antenna 2.

  The first SW 42 is arranged between the first antenna 2 and the first matching circuit 43 and the second matching circuit 45. By switching the first SW 41, the first antenna 2 can be electrically connected to either the first matching circuit 43 or the second matching circuit 45.

  The second SW 44 is arranged between the first matching circuit 43 and the second matching circuit 45 and the radio circuit 3. By switching the second SW 44, the wireless circuit 3 can be electrically connected to either the first matching circuit 43 or the second matching circuit 45.

  Further, the first SW 42 and the second SW 44 are each connected to the frequency control unit 13 and can be switched by instruction information from the frequency control unit 13.

  When the wireless terminal 1 is away from the charging stand 20, the first SW 42 is set so that the first antenna and the first matching circuit 43 are electrically connected, and the second SW 45 is the second SW 45. 1 matching circuit 43 and wireless circuit 3 are set to be electrically connected. As a result, when the first wireless signal is transmitted, the wireless terminal 1 receives the first antenna 2. The received first wireless signal is input to the wireless circuit 3 through the first matching circuit 43.

  On the other hand, when the wireless terminal 1 is placed on the charging stand 20, the detection unit 8 detects the charging stand 20, and when the frequency control unit 13 acquires detection information from the detection control unit 14, the frequency control unit 13 The first SW 42 is switched so that the first antenna 2 and the second matching circuit 45 are electrically connected, and the second SW 44 is switched between the second matching circuit 45 and the radio circuit 3 electrically. Switch to connect. As a result, when the first wireless signal is transmitted, the wireless terminal 1 receives the first antenna 2. Then, the received first wireless signal is input to the wireless circuit 3 through the second matching circuit 45.

As a result, the wireless terminal 1 can prevent the gain deterioration of both the band 1 and the band 6 both when charging with the charging stand 20 and when not charging. Further, since the second antenna 32 is not necessary, the space required for the antenna can be reduced, and the terminal can be downsized. Further, the resonance frequency of the antenna can be controlled for many cases depending on the combination of the matching circuit and the SW.

(Second modification of transmission / reception unit)
FIG. 7 is a diagram illustrating an outline of the configuration of the second modification of the first transmission / reception unit 30. FIG. 8 is a diagram illustrating a specific example of the configuration of the second modification example of the first transmission / reception unit 30.

  As shown in FIGS. 7 and 8, in FIGS. 7 and 8, the wireless terminal 1 includes a transmission / reception unit 50 instead of the transmission / reception unit 30.

  The transceiver 50 includes the first antenna 2, the first matching circuit 51, the second matching circuit 52, the SW 54, the third matching circuit 53, and the wireless circuit 3.

  The first antenna 2, the first matching circuit 51, and the third matching circuit 53 constitute a first transmission / reception unit 57. The first transmitting / receiving unit 58 is configured by the first antenna 2 and the second matching circuit 52.

  The first matching circuit 51 has one end connected to the first antenna 2 and the other end connected to the radio circuit 3.

  The second matching circuit 52 and the third matching circuit 53 are connected in parallel, and the SW 54 is provided between the second matching circuit 52 and the third matching circuit 53 and the first antenna 2. It is arranged. One end of each of the second matching circuit 52 and the third matching circuit 53 is connected to the SW 54, and the other end of each is connected to the GND.

  As described above, the first antenna 2 is directly connected to the first matching circuit 51 and the wireless circuit 3, and either the second matching circuit 52 or the third matching circuit 53 is connected via the SW 54. Can be connected.

  The first antenna 2 resonates at a relatively low frequency of the first antenna by being electrically connected to the third matching circuit 53 in addition to the first matching circuit 51. Further, the first antenna 2 resonates at a relatively high frequency of the second antenna by being electrically connected to the second matching circuit 52 in addition to the first matching circuit 51.

  The first matching circuit 51 is constituted by a reactance 51L, the second matching circuit 52 is constituted by a capacitor 52C and a reactance 52L arranged in parallel, and the third matching circuit 53 is arranged in parallel. A capacitor 53C and a reactance 53L are included.

  The first matching circuit 51 and the third matching circuit 53 are matching circuits for causing the first antenna 2 to resonate in the frequency band of the first antenna, which is a relatively low frequency band.

  The first matching circuit 51 and the third matching circuit 53 are used when the wireless terminal 1 is not charged on the charging stand 20. The first matching circuit 51 and the third matching circuit 53 are in a normal state where the wireless terminal 1 is not placed on the charging stand 20, that is, in a state where the detection unit 8 does not detect the charging stand 20. The constants of the reactance 51L, the capacitor 53C, and the reactance 53L are set so that one antenna 2 has good antenna characteristics in both frequency bands of band1 and band6.

  The first matching circuit 51 and the second matching circuit 52 are matching circuits for causing the first antenna 2 to resonate in the frequency band of the second antenna that is a relatively high frequency.

  The first matching circuit 51 and the second matching circuit 52 are configured so that the first antenna is charged when the wireless terminal 1 is placed on the charging base 20, that is, in a state where the detection unit 8 detects the charging base 20. 2 is a reactance 51L so that the antenna characteristic gain is good in both frequency bands of band1 and band6, that is, the performance of the first antenna 2 is good in a slightly high frequency band in normal times. The constants of the capacitor 52C and the reactance 52L are set.

  The SW 54 is a switch that switches the frequency of the first antenna 2. By switching the SW 54, the first antenna 2 can be electrically connected to either the second matching circuit 52 or the third matching circuit 53 in addition to the first matching circuit 51. Yes.

  The SW 54 is connected to the frequency control unit 13 and can be switched by instruction information from the frequency control unit 13.

  When the wireless terminal 1 is away from the charging stand 20, the SW 54 is set so that the first antenna 2 and the third matching circuit 53 are electrically connected. Accordingly, when the first wireless signal is transmitted, the wireless terminal 1 is adjusted to the first antenna frequency band relatively low by the first matching circuit 51 and the third matching circuit 53. 1 is received by the antenna 2. Then, the received first wireless signal is input to the wireless circuit 3 via the first matching circuit 51.

  On the other hand, when the wireless terminal 1 is placed on the charging stand 20, the detection unit 8 detects the charging stand 20, and when the frequency control unit 13 acquires detection information from the detection control unit 14, the frequency control unit 13 The SW 54 is switched so that the first antenna 2 and the second matching circuit 52 are electrically connected. As a result, when the first wireless signal is transmitted, the wireless terminal 1 is adjusted to the first antenna frequency relatively higher by the first matching circuit 51 and the second matching circuit 52. Is received by the antenna 2. Then, the received first wireless signal is input to the wireless circuit 3 via the first matching circuit 51.

  As a result, the wireless terminal 1 can prevent gain degradation in both the band 1 and the band 6 frequency bands when charging with the charging base 20 and when not charging.

  The frequency adjustment unit 50 only needs to be able to change the gain of the first matching circuit 51 disposed between the first antenna 2 and the radio circuit 3 using the SW 54, and the configuration shown in FIGS. It is not limited. Further, the circuit elements such as capacitors and reactances constituting each of the first matching circuit 51, the second matching circuit 52, and the third matching circuit 53 are not limited to the configuration shown in FIG. It may be configured as follows. This configuration also eliminates the need for the second antenna 32, and also uses only one SW, so that it is possible to reduce the component arrangement space and cost.

(Third modification of transmission / reception unit)
FIG. 9 is a diagram illustrating a configuration of a third modification of transmission / reception unit 30. In FIG. 9, the wireless terminal 1 includes a transmission / reception unit 60 instead of the transmission / reception unit 30. The transmission / reception unit 60 includes a first antenna 2 </ b> F that is an inverted F antenna and a radio circuit 3. As shown in FIG. 9, the first antenna 2 </ b> F is configured to switch the short-circuit point or switch the termination condition of the short-circuit point.

  The first antenna 2F is connected to the element portion 2Fd and GND, is parallel to each other, and is arranged so that the length of the element portion 2Fd is increased in this order, the end portion 2Fa, the end portion 2Fb, and An end 2Fc is provided.

  A feeding point 63 is disposed at the end 2Fa. An SW 61 is disposed at the end 2Fb, and an SW 62 is disposed at the end 2Fc. The feeding point 63 is connected to the wireless circuit 3. Each of the SW 61 and SW 62 is connected to the frequency control unit 13.

  The element part 2Fd, the end part 2Fa, and the end part 2Fc constitute a first transmission / reception part 67. The element portion 2Fd, the end portion 2Fa, and the end portion 2Fb constitute a second transmitting / receiving unit 68.

  By switching so that SW61 is electrically connected and SW62 is electrically cut off, the short-circuit point of the element portion 2Fd becomes the grounding point of the GND of the end portion 2Fc.

  The element portion 2Fd is electrically connected to the end portion 2Fa and the end portion 2Fc, and is electrically disconnected from the end portion 2Fb, thereby resonating at a relatively low frequency of the first antenna.

  The end 2Fc is an end for resonating the first antenna 2F at the frequency of the first antenna that is a relatively low frequency band.

  The frequency of the antenna of the first antenna 2F at which the end 2Fc is a short circuit point is detected in a normal state where the wireless terminal 1 is not placed on the charging base 20, that is, the detection unit 8 detects the charging base 20. In such a state, the antenna is set to have good antenna characteristics in both frequency bands of band1 and band6.

  As a result, when the first wireless signal is transmitted, the wireless terminal 1 receives the signal by the first antenna 2F where the end 2Fc is a short-circuit point. Then, the received first wireless signal is input to the wireless circuit 3 via the feeding point 63.

  On the other hand, by switching so that SW61 is electrically disconnected and SW62 is electrically connected, the short-circuit point of the element portion 2E becomes the grounding point of the GND of the end portion 2Fb.

  The element portion 2Fd is electrically connected to the end portion 2Fa and the end portion 2Fb, and is electrically disconnected from the end portion 2Fc, thereby resonating at a relatively high frequency of the second antenna.

  The end 2Fb is an end for resonating the first antenna 2F at the frequency of the second antenna that is a relatively high frequency band.

  The frequency of the antenna of the first antenna 2F where the end 2Fb is a short-circuit point is the state where the wireless terminal 1 is placed on the charging base 20, that is, the state where the detection unit 8 detects the charging base 20. It is set so that good antenna characteristics are obtained in both frequency bands of band1 and band6.

  Thereby, when the first wireless signal is transmitted, the wireless terminal 1 receives the signal by the first antenna 2F in which the end 2Fb is a short circuit point. Then, the received first wireless signal is input to the wireless circuit 3 via the feeding point 63.

  As a result, the wireless terminal 1 can prevent the gain deterioration of both the band 1 and the band 6 both when charging with the charging stand 20 and when not charging.

  A 2-band inverse F antenna such as band1 and band6 uses the higher-order mode of the normal antenna. However, the frequency at which the first antenna 2F resonates can be changed by changing the short-circuit point in any band of band1 and band6. Further, it is possible to cope with 3 bands or more by increasing the end portion and SW of the first antenna 2F and increasing the number of short-circuit points. Even in this configuration, since the second antenna is unnecessary, the space used by the antenna can be reduced. In addition, since the antenna is matched at the position of the short-circuit point, the number of matching circuits can be reduced.

(Fourth modification of the transceiver)
Next, a fourth modification of the transmission / reception unit will be described using FIG. 10 and FIG.

  FIG. 10 is a diagram illustrating a configuration of a fourth modification of the transmission / reception unit 30. FIG. 11 is a diagram illustrating a configuration of an example of the termination portion in FIG.

  In FIG. 10, the wireless terminal 1 includes a transmission / reception unit 70 instead of the transmission / reception unit 30. The transmission / reception unit 70 includes the first antenna 2E, and the frequency of the first antenna 2E is controlled by whether the excited element is directly connected to the GND or to the GND via the termination unit. It is the composition which is done. In other words, the transmission / reception unit 70 is configured to switch the termination condition of the excited element depending on whether or not the wireless terminal 1 is placed on the charging stand 20.

  The transmission / reception unit 70 includes the first antenna 2E, the excited element 71, the SW 72, the termination unit 73, and the radio circuit 3.

  The first antenna 2E is provided with an element 2E1 for band1 having good antenna characteristics at band1 and an element 2E6 for band6 having good antenna characteristics at band6 on one end side. The first antenna 2E is provided with a feeding point 2P on the other end side, and the tip of the other end is connected to GND.

  A wireless circuit 3 is connected to the feeding point 2P.

  The excited element 71 is disposed adjacent to the first antenna 2E. One end of the excited element 71 faces the first antenna 2E, and the other end is connected to the SW 72.

  The SW 72 is a switch for switching whether the other end of the driven element 71 is electrically connected to the GND via the terminal end 73 or is directly connected to the GND by being switched.

  As shown in FIG. 11, the termination unit 73 includes a parallel resonance circuit of an inductance 73L and a capacitor 73C. A constant is selected for the termination unit 73 so as to be open at a high frequency in the band 6 band.

  The first antenna 2E and the excited element 71 constitute a first transmission / reception unit 77. The first transmitting / receiving unit 78 is configured by the first antenna 2 </ b> E, the excited element 71, and the termination unit 73.

  The week end portion 73 is a matching circuit for resonating the first antenna 2E in the frequency band of the second antenna that is a relatively high frequency band.

  The length of the driven element 71 is adjusted so as to resonate with band 1 during non-contact charging.

  Further, for the element 6E for band 6, the driven element 71 appears to be GND. For this reason, when one end portion (tip portion) of the element 2E6 for the band 6 and one end portion of the driven element 71 are close to each other (similar to the case where other metal objects are close to each other), the first antenna The resonance frequency of 2E is off.

  In this state, the length of the band 6 element 2E6 is adjusted so that the first antenna 2E resonates within the band 6 band. The SW 72 is set so as to connect the driven element 71 directly to the GND.

  As a result, when the first wireless signal is transmitted, the wireless terminal 1 receives the first antenna 2E having the element 2E1 and the element 2E6. Then, the received first radio signal is input to the radio circuit 3 via the feeding point 2P.

  That is, by connecting the excited element 71 directly to the GND, the first antenna 2E resonates at the frequency of the first antenna, which is a relatively low frequency band, and transmits and receives the first radio signal.

  On the other hand, when the wireless terminal 1 is placed on the charging stand 20, the detection unit 8 detects the charging stand 20, and when the frequency control unit 13 acquires detection information from the detection control unit 14, the frequency control unit 13 The SW 72 is switched and the driven element 71 is connected to the GND via the terminal end 73.

  When the first wireless signal is transmitted, the wireless terminal 1 receives the signal via the first antenna 2E having the elements 2E1 and 2E6. Here, by placing the wireless terminal 1 on the charging stand 20, the resonance frequency of the element 2E6 for the band 6 is naturally deviated from the band 6.

  However, due to the termination portion 73 connected to the driven element 71, the driven element 71 does not appear to be GND in the band 6 band, so that the resonance frequency of the first antenna 2E shifts to a higher level. For this reason, the deviation of the frequency and the deviation of the frequency when the wireless terminal 1 is placed on the charging stand 20 are offset. As a result, the wireless terminal 1 can obtain resonance of the first antenna 2 </ b> E with the band 6 even when placed on the charging stand 20.

  That is, by connecting the excited element 71 to the GND via the termination portion 73, the first antenna 2E resonates at the frequency of the second antenna, which is a relatively high frequency band, and the first radio signal Send and receive.

  As described above, the wireless terminal 1 can prevent gain deterioration in both the band 1 and the band 6 frequency bands when charging with the charging stand 20 and when not charging.

  Here, this configuration uses a parasitic element as disclosed in Japanese Patent Application Laid-Open No. 2009-159227, but is different in that gain deterioration can be prevented in both frequency bands of band1 and band6.

(Short range wireless device)
The charging stand 20 may be a short-range wireless device (for example, a FeliCa (registered trademark) reader) that performs short-range wireless communication with the wireless terminal 1.

  FIG. 12 is a diagram schematically illustrating a configuration of a short-range wireless system (distance wireless signal transmission / reception system) including the wireless terminal 101 of the present embodiment.

  The short-range wireless system 109 includes a wireless terminal 101 and a short-range wireless device (external device) 120.

  The wireless terminal 101 is different from the wireless terminal 1 in that a short-range wireless antenna 107 and a detection unit 108 are provided instead of the charging device unit 7 and the detection unit 8. Other configurations of the wireless terminal 101 are the same as those of the wireless terminal 1. Similarly to the wireless terminal 1, the wireless terminal 101 may include the charging device unit 7 and the detection unit 8.

  The short-range wireless antenna 107 transmits / receives a short-range wireless signal to / from a short-range wireless antenna 121 described later of the short-range wireless device 120.

  The detection unit 108 determines whether the wireless terminal 101 is placed on the short-range wireless device 120 and whether the wireless terminal 101 has left the short-range wireless device 120 after wireless communication with the short-range wireless device 120 is completed. Is detected.

  The detection unit 108 detects that the short-range wireless antenna 107 has been placed on the short-range wireless device 120 by detecting that the short-range wireless antenna 107 has started wireless communication with the short-range wireless antenna 121. When the detection unit 108 detects that the short-range wireless antenna 107 has started short-range wireless communication with the short-range wireless antenna 121, the detection unit 108 outputs information indicating that the short-range wireless device 120 has been detected to the detection control unit 14.

  Further, when detecting that the short-range wireless communication between the short-range wireless antenna 107 and the short-range wireless antenna 121 is completed and the wireless terminal 101 is separated from the short-range wireless device 120, the detecting unit 108 detects the short-range wireless Information indicating that the device 120 has been separated is output to the detection control unit 14.

  The detection unit 108 detects that the short-range wireless antenna 107 is performing short-range wireless communication with the short-range wireless antenna 121, and closes short-range wireless communication with the short-range wireless antenna 107 and the short-range wireless antenna 121. After that, it is only necessary to detect that the wireless terminal 101 has moved from the short-range wireless device 120, and there is no particular limitation. As an example, the detection unit 108 can be configured by any one or a plurality of sensors such as a proximity sensor, an acceleration sensor, and a coil detection sensor.

  When the various sensors constituting the detection unit 108 detect that the wireless terminal 101 is separated from the short-range wireless device 120, the SW 33 is switched to connect the first antenna 2 and the wireless circuit 3 to adjust the frequency. The unit 31 is disconnected from the wireless circuit 3.

  The short-range wireless device 120 includes a short-range wireless antenna (antenna) 121 and a control unit 123 for short-range wireless communication with the wireless terminal 101.

  The short-range wireless antenna 121 performs a short-range wireless signal with the short-range wireless antenna 107 included in the wireless terminal 1, and is a known short-range wireless communication standard (for example, FeliCa (registered trademark), ISO / IEC 14443). NFC standards including the like may be used.

  The control unit 123 controls the driving of the short-range wireless antenna 121 and controls the driving of the entire short-range wireless device 120.

  As described above, the short-range wireless system 109 includes the wireless terminal 101 and the short-range wireless device 120 that transmits and receives short-range wireless signals to and from the wireless terminal 101. The first wireless communication can be performed while suppressing the gain degradation of the terminal 101.

(Processing flow of the wireless terminal 101)
Next, a processing flow of the wireless terminal 101 will be described with reference to FIGS. 12 and 13. FIG. 13 is a flowchart showing the processing flow of the wireless terminal 101.

  In the initial state, the SW 33 is set to electrically connect the wireless circuit 3 and the first antenna 2 and to electrically disconnect the wireless circuit 3 and the second antenna 32.

  The wireless terminal 101 performs the first wireless communication through the above-described YES in step S11 and step S12 (step S12).

  Next, in order to perform near field communication, the user places the wireless terminal 101 on the near field apparatus 120. Then, the main control unit 10 drives the control circuit 6, the short-range wireless antenna 107, the short-range wireless antenna 121, and the control unit 123, so that short-range wireless signals are transmitted and received between the short-range wireless antennas 107 and 121. . In this manner, short-range wireless communication is started between the wireless terminal 101 and the short-range wireless device 120.

  The detecting unit 108 detects that the wireless terminal 101 is placed on the short-range wireless device 120 when the short-range wireless antenna 107 starts receiving a short-range wireless signal from the short-range wireless antenna 121 (step S113). YES), information indicating that the short-range wireless device 120 has been detected is output to the detection control unit 14.

  When the detection control unit 14 acquires information indicating that the short-range wireless device 120 has been detected from the detection unit 8, the detection control unit 14 outputs the detection information to the frequency control unit 13. And the frequency control part 13 will switch SW33 to the 2nd antenna 32 side, if detection information is acquired from the detection control part 14. FIG. That is, the process of S14 is performed.

  Then, through the processing of YES in step S15 and step S16, the wireless terminal 1 executes the first wireless communication (step S16).

  Next, when the reception of the short-range wireless signal of the short-range wireless antenna 107 is completed by stopping the short-range wireless signal from the short-range wireless device 120, the detection unit 108 causes the wireless terminal 101 to leave the short-range wireless device 120. It is detected whether or not (step S117).

  When the user moves the wireless terminal 101 away from the short-range wireless device 120, the detection unit 108 detects that the wireless terminal 101 has left the short-range wireless device 120 (YES in step S117), and the short-range wireless device. Information indicating that 120 is separated is output to the detection control unit 14. When the detection control unit 14 acquires information indicating that the short-range wireless device 120 is separated from the detection unit 108, the detection control unit 14 outputs undetected information to the frequency control unit 13.

  When acquiring the non-detection information from the detection control unit 14, the frequency control unit 13 switches the SW 33 to the first antenna 2 side (step S18). That is, when the frequency control unit 13 acquires the undetected information from the detection control unit 14, the radio circuit 3 and the first antenna 31 are electrically connected, and the radio circuit 3 and the second antenna 32 are electrically connected. SW33 is switched to shut off.

(Program and recording medium)
Each control unit in the main control unit 10 of the present invention may be configured by hardware logic. Alternatively, it may be realized by software using a CPU (Central Processing Unit) as follows.

  That is, each control unit of the main control unit 10 develops a CPU such as an MPU that executes instructions of a program that realizes each function, a ROM (Read Only Memory) that stores the program, and a format that can execute the program. A RAM (Random Access Memory) and a storage device (recording medium) such as a memory for storing the program and various data are provided.

  The object of the present invention is not limited to the case where the control program for realizing each control unit of the main control unit 10 is fixedly carried in the program memory, but the program code (executable program, Also achieved by supplying a recording medium recording an intermediate code program or source program) to each control unit of the main control unit 10 and reading and executing the program code recorded on the recording medium. Is possible.

  The recording medium is not limited to a specific structure or type. That is, the recording medium includes, for example, a tape system such as a magnetic tape and a cassette tape, a magnetic disk such as a floppy (registered trademark) disk / hard disk, and an optical disk such as a CD-ROM / MO / MD / DVD / CD-R. System, a card system such as an IC card (including a memory card) / optical card, or a semiconductor memory system such as a mask ROM / EPROM / EEPROM / flash ROM.

  Moreover, even if each control unit of the main control unit 10 is configured to be connectable to a communication network, the object of the present invention can be achieved. In this case, the program code is supplied via a communication network. The communication network is not limited to a specific type or form as long as it can supply a program code to each control unit of the main control unit 10. For example, the Internet, intranet, extranet, LAN, ISDN, VAN, CATV communication network, virtual private network, telephone line network, mobile communication network, satellite communication network, etc. may be used.

  The transmission medium constituting the communication network may be any medium that can transmit the program code, and is not limited to a specific configuration or type. For example, even with wired lines such as IEEE1394, USB, power line carrier, cable TV line, telephone line, ADSL (Asymmetric Digital Subscriber Line) line, infrared rays such as IrDA and remote control, Bluetooth (registered trademark), 802.11 wireless, HDR, mobile phone It can also be used by radio such as a telephone network, a satellite line, and a terrestrial digital network. The present invention can also be realized in the form of a computer data signal embedded in a carrier wave in which the program code is embodied by electronic transmission.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  The present invention can be used for a wireless terminal, a power transmission system, and a short-range wireless signal transmission / reception system capable of transmitting and receiving a wireless signal.

1.101 Wireless terminal 2 First antenna (first transmitter / receiver)
2E 1st antenna 2F 1st antenna 3 Radio circuit 4 3rd antenna 5 Radio circuit 7 Charging device unit 7a Battery 8/108 Detection unit 9 Wireless transmission system (power transmission system)
10 main control unit 11 first radio control unit 12 second radio control unit 13 frequency control unit 20 charging stand (external device)
30 Transmitter / receiver (antenna)
32 Second antenna (second transceiver)
40/50/60/70 Transmitter / Receiver 43 First Matching Circuit 45 Second Matching Circuit 47/57/67/77 First Transmitter / Receiver 48/58/68/78 Second Transmitter / Receiver 51 First Matching Circuit 107 Short-range wireless antenna 107/121 Short-range wireless antenna 109 Short-range wireless system 120 Short-range wireless device 121 Short-range wireless antenna 123 Control unit

Claims (10)

A wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device,
A detection unit for detecting whether or not the external device has been contacted;
The first transmission / reception unit that transmits / receives a wireless signal used for the wireless communication by resonating at a first frequency when separated from the external device, and the first transmission / reception unit that is in contact with the external device A second transmitting / receiving unit that transmits and receives the wireless signal by resonating at a second frequency higher than the frequency; and
With
When the transmission / reception unit is away from the external device, the first transmission / reception unit transmits and receives the radio signal.
When the detection unit detects that it has contacted the external device,
The wireless terminal, wherein the transmission / reception unit transmits / receives the wireless signal by the second transmission / reception unit. A wireless terminal capable of performing wireless communication and performing a predetermined operation by contacting or approaching an external device,
A detection unit for detecting whether or not the external device has been contacted;
An antenna for performing the wireless communication;
A frequency control unit for correcting the frequency of the antenna,
When the detection unit detects contact with the external device,
A radio terminal, wherein the frequency control unit corrects the frequency characteristics of the antenna so as to be favorable in a frequency band used in the radio communication.   2. The wireless terminal according to claim 1, wherein when the detection unit detects that it is separated from the external device, the transmission / reception unit transmits and receives the wireless signal by the first transmission / reception unit. The first transmission / reception unit includes a first antenna,
A switching unit that switches driving of the first and second transmission / reception units;
The wireless terminal according to claim 1, further comprising: a frequency control unit that controls a frequency at which the transmission / reception unit resonates by controlling switching of the switching unit. The first antenna resonates at the first frequency;
The wireless terminal according to claim 4, wherein the second transmitting / receiving unit includes a second antenna that resonates at the second frequency.   5. The radio according to claim 4, wherein the second transmission / reception unit includes the first antenna and a matching circuit for causing the first antenna to resonate at the second frequency. Terminal.   The wireless terminal according to claim 6, wherein the first transmitting / receiving unit includes a matching circuit for causing the first antenna to resonate at the first frequency. The first antenna is an inverted F antenna,
The inverted F antenna has an element part and first and second ends for grounding the element part at different positions,
The first transmission / reception unit includes the element unit and the first end,
The second transmission / reception unit includes the element unit and the second end.
The wireless terminal according to claim 6, wherein the switching unit switches electrical connection between the element unit and the first or second end. The second transmission / reception unit includes an excited element,
The wireless terminal according to claim 6, wherein the switching unit switches electrical connection between the excited element and the matching circuit. The radio signal consists of a plurality of different frequency bands,
The said 1st or 2nd transmission / reception part transmits / receives the radio signal which consists of these said several frequency bands by resonating at the said 1st or 2nd frequency. The wireless terminal according to any one of the above.

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