JP2015061110A - Electronic device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable electronic device capable of suppressing quality degradation of a reception signal which may be generated due to combinations of bands as much as possible, when a plurality of bands are used at the same time.SOLUTION: A mobile terminal 1 has a plurality of antennas suitable for radio communication respectively in which an individual frequency band is used. The mobile terminal 1 detects a holding state by a user. The mobile terminal 1, when performing radio communication in which first and second frequency bands are used, selects two antennas from the plurality of antennas, on the basis of the detected holding state. The mobile terminal 1, when the frequency band suitable for the selected antenna is different from the first and second frequency bands, changes at least one of a resonant frequency and a matching state of the selected antenna. The mobile terminal 1 performs radio communication using the selected two antennas.

Description

  The present invention relates to a portable electronic device provided with a plurality of antennas.

  In a mobile communication terminal equipped with a plurality of antennas, there is an antenna used for communication in order to reduce the quality degradation of received signals during a call and data communication (hereinafter, call and data communication are collectively referred to as communication) as much as possible. May be switched. For example, in the technique described in Japanese Patent Application Laid-Open No. 2012-105124 (Patent Document 1), the electric field strength at an original antenna for a wireless function is smaller than a threshold value, and the electric field strength at another antenna for a wireless function is a threshold value. If it is larger, or if the total electric field strength at the plurality of antennas is large, antenna switching is performed.

JP 2012-105124 A

  In recent years, operation of a system that simultaneously uses a plurality of bands (frequency bands) such as SV-LTE (Simultaneous Voice and LTE (registered trademark)) using a plurality of communication schemes and carrier aggregation has been started. In this case, depending on the combination of bands, the harmonics of one transmission wave may become the interference wave of the other reception wave, or the intermodulation wave of multiple transmission waves may become the interference wave of one of the reception waves There can be. However, the above-described patent document only describes switching of an antenna used for communication according to the electric field strength, and does not disclose a technique that can sufficiently cope with the above problem.

  An object of the present invention is to provide a portable electronic device capable of suppressing as much as possible quality degradation of a received signal that may be caused by a combination of bands when a plurality of bands are used simultaneously.

  According to one aspect of the present invention, a portable electronic device includes a plurality of antennas each adapted to wireless communication using individual frequency bands, a detection unit that detects a gripping state of the electronic device, and a first frequency. A selection means for selecting two antennas from the plurality of antennas based on the detected gripping state when performing wireless communication using a band and a second frequency band; and the selected antenna And adjusting means for changing at least one of a resonance frequency and a matching state of the selected antenna when the frequency band of which the frequency is suitable is different from the first frequency band and the second frequency band, and the selected two And a communication interface for wireless communication using an antenna.

  ADVANTAGE OF THE INVENTION According to this invention, when using a some band simultaneously, the quality degradation of the received signal which may arise by the combination of a band can be suppressed as much as possible.

2 is a diagram for explaining a schematic configuration of a mobile terminal 1. FIG. It is a figure for demonstrating the antenna to be used in the case of using a single band by a single communication system. It is a figure showing the example of the combination of the band used in SV-LTE, the example of the combination of the band used in carrier aggregation, and the presence or absence of generation | occurrence | production of the interference wave in the example of each combination. It is a figure for demonstrating the jamming wave produced when using the band 13 of LTE and the subclass 1 of the band class 0 of CDMA2000. It is a figure for demonstrating the jamming wave which arises when using both the band 4 and the band 17 of LTE. It is a figure for demonstrating the holding state of the portable terminal. It is a figure showing the antenna switching table 32. FIG. 2 is a diagram illustrating a hardware configuration of a mobile terminal 1. FIG. 2 is a block diagram schematically showing a configuration of a main part of the mobile terminal 1. FIG. FIG. 10 is a circuit diagram illustrating an example of a first matching circuit 421 in FIG. 9. It is a figure which shows an example of the antenna matching table 33 memorize | stored in the memory | storage part 300 of FIG. 3 is a diagram for describing a functional configuration of a mobile terminal 1. FIG. 4 is a flowchart showing a process flow of the mobile terminal 1. It is a flowchart showing the flow of processing of portable terminal 1A. It is a figure for demonstrating schematic structure of 1 A of portable terminals. It is a figure for demonstrating the area | region of the main surface of 1 A of portable terminals. It is a figure showing the schematic structure of the data table D17.

  Hereinafter, a mobile terminal according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated. In addition, as a portable terminal, a smart phone and a tablet terminal are mentioned, for example. The portable terminal is not particularly limited as long as it is a portable electronic device capable of wireless communication.

<A. Schematic configuration of mobile terminal 1>
FIG. 1 is a diagram for explaining a schematic configuration of a mobile terminal 1 according to an embodiment of the present invention. Specifically, FIG. 1 is a front view of the mobile terminal 1. Referring to FIG. 1, mobile terminal 1 includes a touch screen 108 and operation keys 105 on the main surface. Note that the touch screen 108 includes a display and a touch panel.

  Moreover, the portable terminal 1 is provided with grip sensors 191 to 194 in the peripheral part (two side parts) of the housing. Specifically, two grip sensors are arranged on each of the two side surfaces facing each other among the four side surfaces of the mobile terminal 1. The two side surfaces are side surfaces in the longitudinal direction of the mobile terminal 1.

  Each of the grip sensors 191 to 194 generates a predetermined signal when detecting a hand contact. The signal is sent to the CPU 101. When the user holds the mobile terminal 1 with the right hand, for example, when a finger is placed on one grip sensor 191, only one grip sensor 191 among the four grip sensors 191 to 194 generates the signal.

  The mobile terminal 1 includes a first antenna 121, a second antenna 122, and a third antenna 123 in the housing 10. The first antenna 121 is fed by a feed line (not shown). The feeding point P <b> 1 is a connection point between the feeding line and the first antenna 121. The second antenna 122 is fed by a feed line (not shown). The feeding point P <b> 2 is a connection point between the feeding line and the second antenna 122. Further, the third antenna 123 is fed by a feed line (not shown). The feeding point P3 is a connection point between the feeding line and the third antenna 123.

  In addition, the mobile terminal 1 rotates the display screen of the display 90 degrees when the attitude of the mobile terminal 1 changes from the horizontal attitude to the vertical attitude, or when the attitude changes from the vertical attitude to the horizontal attitude. Has a screen rotation function.

  The portable terminal 1 uses a plurality of communication methods or a plurality of bands (frequency bands) at the same time. If a specific example is given, the portable terminal 1 will be a unit band with communication using SV-LTE (Simultaneous voice and LTE (registered trademark)), communication using carrier aggregation, and a single communication method in a certain aspect. Execute any one of the communications using. SV-LTE provides LTE (registered trademark) data communication and CDMA (Code Division Multiple Access) voice communication simultaneously. The reason why CDMA is used for voice communication is that LTE (Long Term Evolution) generally does not define a circuit switching mechanism for exchanging voice.

<B. Antenna and band (frequency band)>
FIG. 2 is a diagram for explaining an antenna to be used when a single band is used in a single communication method. Referring to FIG. 2, the antenna third antenna 123 is used in LTE band 4 (frequency band 1700/2100 MHz), the first antenna 121 is used in band 13 (frequency band 700 MHz), and band 17 (frequency band 700 MHz). ) Uses the first antenna 121. The second antenna 122 is used in subclass 1 (frequency band 800 MHz) of band class 0 of CDMA2000 (registered trademark). As described above, the first to third antennas 121 to 123 are antennas suitable for wireless communication using individual frequency bands.

  FIG. 3 is a diagram illustrating an example of a combination of bands used in SV-LTE, an example of a combination of bands used in carrier aggregation, and whether or not an interference wave is generated in each combination example.

  Referring to FIG. 3, mobile terminal 1 uses LTE band 4 and CDMA2000 band class 0 subclass 1 in the case of SV-LTE. Alternatively, the mobile terminal 1 uses the LTE band 13 and the subclass 1 of the band class 0 of CDMA2000. That is, the mobile terminal 1 performs voice and data communication by any one of the two combinations. In the case of a combination of LTE band 4 and CDMA2000 band class 0 subclass 1, no interference is generated. However, in the case of a combination of LTE band 13 and CDMA2000 band class 0 subclass 1, interference is present. Waves are generated.

  In the case of carrier aggregation, the mobile terminal 1 uses the LTE band 4 and the LTE band 13. Alternatively, the mobile terminal 1 uses the LTE band 4 and the LTE band 17. That is, the mobile terminal 1 performs data communication by any one of the two combinations. In the case of the combination of the LTE band 4 and the LTE band 13, no interference wave is generated. However, in the case of the combination of the LTE band 4 and the LTE band 17, an interference wave is generated. Hereinafter, the reason why the interference wave is generated will be described separately in the case of SV-LTE and the case of carrier aggregation.

  FIG. 4 is a diagram for explaining an interference wave generated when the LTE band 13 and the subclass 1 of the band class 0 of CDMA2000 are used. Referring to FIG. 4, the frequency of transmission signal Tx included in subclass 1 of band class 0 of CDMA2000 is f1, and the frequency of transmission signal Tx included in band 13 of LTE is f2. Then, the frequency of the third-order intermodulation distortion signal is represented by 2 × f1−f2 and 2 × f2−f1.

  When specific numerical values are applied, 2 × f1 is determined by the transmission signal Tx (f1 = 824-849 MHz) included in the subclass 1 of the band class 0 and the transmission signal Tx (f2 = 776-786 MHz) included in the band 13. A third-order intermodulation signal of −f2 = 862-922 MHz is generated. This third-order intermodulation signal may be an interference wave having a frequency that matches the reception signal Rx (869-894 MHz) included in subclass 1 of band class 0 of CDMA2000. Similarly, a third-order intermodulation signal of 2 × f2-f1 = 703-748 MHz is also generated. This third-order intermodulation signal can be an interference wave having a frequency that matches the reception signal Rx (746-756 MHz) of the LTE band 13.

  FIG. 5 is a diagram for explaining an interference wave generated when both LTE band 4 and band 17 are used. Referring to FIG. 5, the frequency of the second harmonic (2H) of the transmission signal Tx (704-716 MHz) included in band 17 is 1408-1432 MHz, and the frequency of the third harmonic (3H) is 211-12148 MHz. Become. Since the frequency of the third harmonic wave overlaps with the frequency (2110-2155 MHz) of the reception signal Rx in band 4, it can be an interference wave.

  In the following description, a case where the mobile terminal 1 uses a combination of bands in which an interference wave is generated in each of SV-LTE and carrier aggregation will be described as an example. That is, when the mobile terminal 1 is SV-LTE, the LTE band 13 and the subclass 1 of the CDMA2000 band class 0 are used, and when carrier aggregation is used, the LTE band 4 and the band 17 are used. The case where it does is demonstrated.

<C. Overview of antenna selection (switching) processing>
FIG. 6 is a diagram for explaining a gripping state of the mobile terminal 1. FIG. 6A shows a state in which the user holds the mobile terminal 1 in the vertical direction (vertical orientation) and grips the lower right portion of the mobile terminal 1 with the right hand (hereinafter also referred to as “state A”). Represents. In the state A, the surface of the casing near the feeding point P1 of the first antenna 121 is covered with the right hand. For this reason, the antenna performance of the 1st antenna 121 deteriorates compared with the case where the housing | casing surface near the feeding point P1 is not covered with the hand. Since the user's right hand contacts the grip sensor 194, the grip sensor 194 sends a predetermined signal to the control unit 200 (CPU 101) described later.

  FIG. 6B shows a state when the user holds the portable terminal 1 in the vertical direction (vertical orientation) and holds the lower left portion of the portable terminal 1 with the left hand (hereinafter also referred to as “state B”). Represents. In the state B, the surface of the casing near the feeding point of any antenna is not covered with the left hand. Since the user's left hand contacts the grip sensor 192, the grip sensor 192 sends a predetermined signal to the control unit 200 described later.

  FIG. 6C shows a state when the user is in the horizontal direction (horizontal orientation) of the mobile terminal 1 and holds the lower right portion of the mobile terminal 1 with the right hand (hereinafter also referred to as “state C”). Represents. In the state C, the housing surface in the vicinity of the feeding point P2 of the second antenna 122 is covered with the right hand. For this reason, the antenna performance of the second antenna 122 is deteriorated as compared with the case where the surface of the housing in the vicinity of the feeding point P2 is not covered with the hand. Further, since the user's right hand contacts the grip sensor 193, the grip sensor 193 sends a predetermined signal to the control unit 200 described later.

  FIG. 6D shows a state when the user holds the mobile terminal 1 in the horizontal direction (horizontal orientation) and holds the lower left portion of the mobile terminal 1 with the left hand (hereinafter also referred to as “state D”). Represents. In the state D, the housing surface in the vicinity of the feeding point P1 of the first antenna 121 is covered with the left hand. For this reason, the antenna performance of the 1st antenna 121 deteriorates compared with the case where the housing | casing surface near the feeding point P1 is not covered with the hand. Further, since the user's right hand contacts the grip sensor 194, the grip sensor 194 sends a predetermined signal to the control unit 200 described later.

  FIG. 7 is a diagram showing the antenna switching table 32. In the antenna switching table 32, information for identifying an antenna to be used is recorded for each communication type and each band to be used for each of the states A to D shown in FIG. Further, the antenna switching table 32 records whether or not it is necessary to adjust the characteristics of the antenna to be used (resonance frequency and matching state adjustment).

  By the way, in the case of SV-LTE, the portable terminal 1 uses the LTE band 13 and the subclass 1 of the band class 0 of CDMA2000 as described above. For this reason, the mobile terminal 1 originally has the first antenna 121 (setting 2) for LTE band 13 and the second antenna 122 for subclass 1 of band class 0 of CDMA2000, with reference to FIG. (Setting 4) is used.

  However, as described above, the mobile terminal 1 may generate an interference wave in the combination of the LTE band 13 and the subclass 1 of the band class 0 of CDMA2000. For this reason, the portable terminal 1 changes the combination of the antennas used for SV-LTE. More specifically, since the reception sensitivity is significantly reduced when the surface of the casing near the feeding point is covered with a hand, the mobile terminal 1 includes an antenna having a feeding point whose surface of the surrounding casing is covered with a hand. The combination of antennas used for SV-LTE is changed so as not to use. Specifically, the mobile terminal 1 changes the combination of antennas used for SV-LTE from a default combination to a preferable combination based on the antenna switching table 32.

  For example, in the state A and the state D, the mobile terminal 1 changes the antenna used for the LTE band 13 from the default first antenna 121 to the third antenna 123. In this case, the portable terminal 1 adjusts the characteristics of the third antenna 123 that is the antenna after the change as the antenna is changed. In the state C, the mobile terminal 1 changes the antenna used for the subclass 1 of the band class 0 of CDMA2000 from the default second antenna 122 to the third antenna 123. In this case, the portable terminal 1 adjusts the characteristics of the third antenna 123 that is the antenna after the change as the antenna is changed.

  In the case of carrier aggregation, the mobile terminal 1 uses the LTE band 4 and the LTE band 17 as described above. For this reason, the mobile terminal 1 originally refers to FIG. 2 with reference to the third antenna 121 for LTE band 4 (setting 1) and the first antenna 121 for LTE band 17 (setting 3). And use.

  However, as described above, the mobile terminal 1 may generate an interference wave in the combination of the LTE band 4 and the LTE band 17. For this reason, the portable terminal 1 changes the combination of the antennas used for carrier aggregation. More specifically, since the reception sensitivity is significantly reduced when the surface of the casing near the feeding point is covered with a hand, the mobile terminal 1 includes an antenna having a feeding point whose surface of the surrounding casing is covered with a hand. The combination of antennas used for carrier aggregation is changed so that is not used. Specifically, based on the antenna switching table 32, the mobile terminal 1 changes the combination of antennas used for carrier aggregation from a default combination to a preferable combination.

  For example, in the state A and the state D, the mobile terminal 1 changes the antenna used for the LTE band 17 from the default first antenna 121 to the second antenna 122. In this case, the portable terminal 1 adjusts the characteristics of the second antenna 122 that is the antenna after the change as the antenna is changed.

  As described above, the portable terminal 1 uses a combination of antennas to be used when there is a possibility that the reception sensitivity of the antennas may be lowered by a user's hand when using a combination of bands that may cause an interference wave. At the same time, the antenna characteristics are changed from the default antenna. Therefore, according to the mobile terminal 1, when a plurality of bands are used at the same time as described above, it is possible to suppress as much as possible the deterioration of the received signal quality that may occur due to the combination of the bands.

<D. Hardware configuration of portable terminal 1>
FIG. 8 is a diagram illustrating a hardware configuration of the mobile terminal 1. Referring to FIG. 8, the mobile terminal 1 includes a CPU 101 that executes a program, a ROM (Read Only Memory) 102, a RAM (Random Access Memory) 103, a flash memory 104, an operation key 105, a speaker 106, and the like. The camera 107, the touch screen 108, the acceleration sensor 111, the wireless communication IF (Interface) 112, the first antenna 121, the second antenna 122, the third antenna 123, and the grip sensors 191 to 194, It is configured to include at least. The touch screen 108 includes the display 1081 and the touch panel 1082 as described above. The components 101 to 108, 111, 112, and 191 to 194 are connected to each other by a data bus.

  The first to third antennas 121 to 123 are connected to the wireless communication IF 112. The first to third antennas 121 to 123 and the wireless communication IF 112 are used for wireless communication with other mobile terminals, fixed telephones, and PCs (Personal Computers) via a base station, for example.

  The ROM 102 is a nonvolatile semiconductor memory. The ROM 102 stores a boot program for the portable terminal 1 in advance. The flash memory 104 is a nonvolatile semiconductor memory. The flash memory 104 may be configured as a NAND type as an example. The flash memory 104 volatilizes various data such as an operating system of the mobile terminal 1, various programs for controlling the mobile terminal 1, data generated by the mobile terminal 1, and data acquired from an external device of the mobile terminal 1. To store.

The processing in the mobile terminal 1 is realized by each hardware and software executed by the CPU 101. Such software may be stored in the flash memory 104 in advance. The software may be stored in a memory card or other storage medium (not shown) and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the so-called Internet. Such software is downloaded via the antennas 121 and 122 and the wireless communication IF 112 and then temporarily stored in the flash memory 104. The software is read from the flash memory 104 by the CPU 101 and further stored in the flash memory 104 in the form of an executable program. The CPU 101 executes the program.

  An essential part of the present invention can be said to be software stored in the flash memory 104 or other storage medium, or software that can be downloaded via a network. The recording medium is not limited to DVD-ROM, CD-ROM, FD, and hard disk, but is fixed such as semiconductor memory such as magnetic tape, cassette tape, optical disk, optical card, mask ROM, EPROM, EEPROM, and flash ROM. A medium carrying a program may be used. The recording medium is a non-temporary medium that can be read by the computer. The program here includes not only a program directly executable by the CPU but also a program in a source program format, a compressed program, an encrypted program, and the like.

  FIG. 9 is a block diagram schematically showing a configuration of a main part of the mobile terminal 1. Referring to FIG. 9, mobile terminal 1 includes transceivers 11 and 21, power amplifiers (PA) 12 and 22, duplexers 13 and 23, antenna control device 20, and first to third antennas 121. -123, the control part 200, and the memory | storage part 300 are included.

  The transceivers 11 and 21 up-convert the transmission baseband signal received from the control unit 200 into a radio frequency band signal. The signals up-converted by the transceivers 11 and 21 are amplified by the power amplifiers PA12 and 22, respectively, thereby generating transmission signals Tx (1) and Tx (2). The transceivers 11 and 21 further generate reception baseband signals by down-converting the reception signals Rx (1) and Rx (2) received via the first to third antennas 121 to 123, respectively. Hereinafter, the transceivers 11 and 21 may be collectively referred to as “signal generation unit 10”.

  The duplexers 13 and 23 are components used to share one antenna for the transmission signal Tx and the reception signal Rx. Each of the duplexers 13 and 23 is provided with a filter that passes the transmission signal Tx and blocks the reception signal Rx, and a filter that passes the reception signal Rx and blocks the transmission signal Tx.

  The antenna control device 20 includes an antenna switching device 411, a first matching circuit 421, a second matching circuit 422, and a third matching circuit 423.

  The antenna switching device 411 is a switch group that switches connections between the antenna-side nodes of the duplexers 13 and 23 and the feeding points of the first to third antennas 121 to 123 in accordance with instructions from the control unit 200. Each of the first antennas 121 to 123 is put into use by being connected to one of the nodes on the antenna side of the duplexers 13 and 23.

  The first matching circuit 421 is a variable matching circuit for the first antenna 121. The second matching circuit 422 is a variable matching circuit for the second antenna 122. The third matching circuit 423 is a variable matching circuit for the third antenna 123. That is, the antenna control device 20 includes a plurality of matching circuits used for each of the plurality of antennas 121 to 123 that are respectively adapted to wireless communication using individual frequency bands.

  The control unit 200 corresponds to the CPU 101 that controls the operation of the entire mobile terminal 1. The wireless communication IF 112 includes a modem (not shown). The modem generates a transmission baseband signal by modulating the digital signal into a signal format used when communicating with the base station. The modem further demodulates the received baseband signal generated by the transceiver.

  The control unit 200 sets the frequency of the local oscillator of the transceivers 11 and 21 so as to be operable in the communication method / band used for communication. Furthermore, the control unit 200 controls the antenna control device 20 with a control signal. The control unit 200 instructs switching of antennas and adjustment of antenna matching by the matching circuit.

  The mobile terminal 1 communicates with the base station in the set frequency band (band), and a channel to be used in the frequency band is designated by the base station. After the channel to be used is designated by the base station, the control unit 200 controls the transceivers 11 and 21 to perform communication using the channel.

  The storage unit 300 includes a program, transmission / reception data, application data, and the like. An antenna switching table 32 and an antenna matching table 33, which will be described later, are also stored in the memory 31.

  FIG. 10 is a circuit diagram showing an example of the first matching circuit 421 of FIG. Note that the second matching circuit 422 and the third matching circuit 423 also have the same circuit configuration as the first matching circuit 421, and therefore the description of the second matching circuit 422 and the third matching circuit 423 is not repeated here.

  Referring to FIG. 10, first matching circuit 421 includes inductor elements 44 and 45 and variable capacitance element 46. The inductance values of the inductor elements 44 and 45 are L1 (nH) and L2 (nH), respectively, and the capacitance value of the variable capacitance element 46 is C1 (pF).

  Inductor element 44 is connected between input / output nodes 42 and 43, inductor element 45 is connected between input / output node 42 and ground node GND, and variable capacitance element 46 is connected between input / output node 43 and ground node. Connected between. One of the input / output nodes 42 and 43 is connected to the antenna ANT3. The other of the input / output nodes 42 and 43 is connected to the antenna control device 20 so as to be connected to one of the duplexers 13 and 23 when the antenna ANT3 is put into use.

  As the variable capacitance element 46, for example, a variable capacitance diode (also referred to as a varicap or a varactor) can be used. Alternatively, a variable capacitance element that changes the capacitance value by switching the number of capacitors connected in parallel by a switch can be used, or the distance between the electrodes of the capacitor can be reduced using MEMS (Micro Electro Mechanical System). It is also possible to use a variable capacitance element of a variable type.

  Unlike the configuration of FIG. 10, the capacitive element may have a constant capacitance value, and the inductance of the inductor element may be variable, or both the capacitance value of the capacitive element and the inductance of the inductor element may be variable. Also good.

  FIG. 11 is a diagram illustrating an example of the antenna matching table 33 stored in the storage unit 300 of FIG. Referring to FIG. 12, the set value of capacitance value C1 (pF) of variable capacitance element 46 in FIG. 10 is determined according to the communication standard / band used in first to third antennas 121 to 123. The inductance values L1 and L2 (nH) of the inductor elements 44 and 45 are fixed values.

<E. Functional configuration of mobile terminal 1>
FIG. 12 is a diagram for explaining a functional configuration of the mobile terminal 1. Referring to FIG. 12, the mobile terminal 1 includes a touch screen 108, an acceleration sensor 111, a wireless communication IF 112, a first antenna 121, a second antenna 122, a third antenna 123, and grip sensors 191 to 194. And a control unit 200 and a storage unit 300.

  The wireless communication IF 112 includes an antenna switching processing unit 410 and an antenna characteristic adjustment unit 420. The antenna switching processing unit 410 corresponds to the antenna switching device 411 in FIG. The antenna characteristic adjustment unit 420 corresponds to the first to third matching circuits 421 to 423.

  The control unit 200 includes a state detection unit 210, a communication control unit 230, and a display control unit 240. The communication control unit 230 includes a selection unit 231. As described above, the storage unit 300 stores the antenna switching table 32 and the antenna matching table 33.

  The acceleration sensor 111 detects the current orientation (portrait or landscape) of the mobile terminal 1 by gravity and detects the acceleration of the mobile terminal 1 due to the user's operation. The acceleration sensor 111 sends the measured acceleration information to the control unit 200. More specifically, the acceleration sensor 111 sends the measured acceleration information to the state detection unit 210 and the display control unit 240.

  When the display control unit 240 detects that the posture of the mobile terminal 1 has changed from the first posture (for example, vertical) to the second posture (for example, horizontal) based on the output from the acceleration sensor 111, the display control unit 240 Rotate the display screen 90 degrees. That is, the display control unit 240 has a screen rotation function.

  The state detection unit 210 detects the gripping state of the mobile terminal 1 by the user based on the output signal from the acceleration sensor 111 and the output signals from the grip sensors 191 to 194. Further, the state detection unit 210 determines whether the hand in contact with the mobile terminal 1 is the left hand or the right hand.

  The communication control unit 230 controls communication using the wireless communication IF 112. Specifically, the communication control unit 230 performs various processes necessary for setting wireless communication.

  The selection unit 231 of the communication control unit 230 selects two antennas used for communication from the first to third antennas 121 to 123 based on the detected gripping state. Specifically, the selection unit 231 performs a plurality of antennas (that is, based on the gripping state detected by the state detection unit 210 when performing wireless communication using the first frequency band and the second frequency band. Two antennas are selected from the first, second, and third antennas 121-123). Specifically, the selection unit 231 refers to the antenna switching table 32 illustrated in FIG. 7 and selects two antennas to be used in each communication method from the first to third antennas 121 to 123. . The selection unit 231 notifies the antenna switching processing unit 410 of the two selected antennas.

  In the case of SV-LTE, combinations of the first frequency band and the second frequency band include a combination of LTE band 13 and CDMA2000 band class 0 subclass 1. In the case of carrier aggregation, as a combination of the first frequency band and the second frequency band, a combination of the LTE band 4 and the LTE band 17 may be mentioned. Moreover, since the specific method for selecting the antenna has been described with reference to FIGS. 6 and 7, the description thereof will not be repeated here.

  The wireless communication IF 112 performs wireless communication with the communication device using the selected two antennas. Specifically, the antenna switching processing unit 410 of the wireless communication IF 112 switches the antenna as necessary so that communication can be performed using the selected antenna.

  When performing wireless communication, the antenna characteristic adjustment unit 420 adjusts the characteristics of the selected antenna when the frequency band suitable for the selected antenna is different from the first frequency band and the second frequency band. Specifically, the antenna characteristic adjustment unit 420 is the antenna that is not the default antenna of the two selected antennas (the third antenna (see FIG. 7 in the case of state A and SV-LTE in FIG. 6)). ) Adjust the antenna characteristics.

  Specifically, the characteristics of the antenna are changed by changing the capacitance of the variable capacitance element 46 of the matching circuit for the antenna that is not the default antenna among the first to third matching circuits 421 to 423. More specifically, among the first to third matching circuits 421 to 423, the capacitance of the variable capacitance element 46 of the matching circuit for the antenna that is not the default antenna is set to a value in which the impedance of the antenna is determined in advance. Change to be. Specifically, the antenna characteristic adjustment unit 420 refers to the antenna matching table 33 and changes the capacitance of the variable capacitance element 46.

<F. Control structure>
FIG. 13 is a flowchart showing a process flow of the mobile terminal 1. Referring to FIG. 13, CPU 101 of portable terminal 1 determines whether or not a communication end request has been made for communication with the base station in step S <b> 2. When CPU 101 determines that a communication end request has been made (YES in step S2), the series of processing ends. If there is no request for termination of communication (NO in step S2), CPU 101 determines in step S4 whether a plurality of bands (a plurality of bands in a plurality of communication methods) are simultaneously used.

  When CPU 101 determines that a plurality of bands are simultaneously used (YES in step S4), CPU 101 determines in step S6 whether the reception band is a combination of bands that are disturbed. When CPU 101 determines that a plurality of bands are not used simultaneously (NO in step S4), the process returns to step S2.

  If the CPU 101 determines that the combination of the bands is affected (YES in step S6), the CPU 101 determines the posture (vertical direction, horizontal direction) of the mobile terminal 1 based on the output signal from the acceleration sensor 111 in step S8. To do. When CPU 101 determines that the combination is not a band that is disturbed (NO in step S6), CPU 101 returns the process to step S2.

  In step S <b> 10, the CPU 101 detects a combination of grip sensors in contact with the hand based on output signals from the grip sensors 191 to 194. In step S <b> 12, the CPU 101 refers to the antenna switching table 32 and selects two antennas to be used based on the detected combination of grip sensors. In step S <b> 14, the CPU 101 refers to the antenna matching table 33 and adjusts the antenna characteristics of the antenna that is changed from the default antenna among the antennas to be used (that is, the antenna that needs adjustment among the two antennas to be used). To do. In step S16, the CPU 101 switches circuits and sets the selected antenna to a usable state.

<G. Modification>
(G1. Other methods of antenna selection)
In the above, the grip state of the user's portable terminal 1 was detected using the grip sensors 191 to 194. However, the gripping state detection method is not limited to this. For example, a mobile terminal (hereinafter referred to as “mobile terminal 1A” for convenience of description) may detect the gripping state as follows. FIG. 15 is a diagram for explaining a schematic configuration of the mobile terminal 1A. FIG. 15A is a front view of the mobile terminal 1A. FIG. 15B is a rear view of the mobile terminal 1. FIG. 15C is a side view of the mobile terminal 1A.

  Referring to FIGS. 15A and 15C, mobile terminal 1A includes a touch screen 108 and operation keys 105 on the main surface. Moreover, 1 A of portable terminals are provided with the side touch sensors 110a, 110b, 110c, 110d on each side. Each side touch sensor 110a, 110b, 110c, 110d is provided on the surface of the housing 10 of the mobile terminal 1A.

  Each of the side surface touch sensors 110a, 110b, 110c, and 110d can be configured by a capacitive sensor, for example. Further, instead of a touch sensor such as a capacitive sensor, a hover compatible touch panel may be used. In the case of a terminal with a narrow frame, an electric field also circulates to the side surface of the housing, so that it is possible to detect the contact position of a finger or hand on the side of the housing. Hereinafter, the four side touch sensors 110a, 110b, 110c, and 110d are collectively referred to as “side touch sensors 110”. That is, the side touch sensor 110 includes four side touch sensors 110a, 110b, 110c, and 110d.

  Referring to FIG. 15B, mobile terminal 1A includes camera 107 and back touch sensor 109 on the back. Similar to the side touch sensor 110, the back surface touch sensor 109 can be constituted by, for example, a capacitive sensor.

  As described above, the mobile terminal 1 </ b> A includes the back surface touch sensor and the side surface touch sensor on each side instead of the grip sensors 191 to 194. Note that the mobile terminal 1 </ b> A includes a first antenna 121, a second antenna 122, and a third antenna 123, similar to the mobile terminal 1.

  More specifically, the mobile terminal 1 </ b> A includes a display control unit 240, a state detection unit 210, a communication control unit 230, and a movable region estimation unit in the control unit 200.

  The back surface touch sensor 109 and each side surface touch sensor 110 send the coordinate information of the detected contact position to the state detection unit 210 of the control unit 200.

  As described above, the state detection unit 210 detects the gripping state of the mobile terminal 1A by the user. Further, the state detection unit 210 determines whether the hand in contact with the mobile terminal 1A is the left hand or the right hand based on the contact position.

  The detection of the gripping state will be described in detail as follows. The state detection unit 210 detects the gripping state based on the coordinate information from the touch panel 1082, the coordinate information from the back touch sensor 109, the coordinate information from each side touch sensor 110, and the acceleration information from the acceleration sensor 111. To do. In more detail, the state detection unit 210 includes information on the detected contact position, posture information (portrait or landscape) of the mobile terminal 1A, and holding information indicating whether the hand in contact is the left hand or the right hand. The gripping state is detected based on the hand information.

  The state detection unit 210 sends the detected gripping state to the movable region estimation unit. Specifically, the state detection unit 210 sends hand contact position information, posture information of the mobile terminal 1A, and handle information as information representing the gripping state to the movable region estimation unit.

  The movable region estimation unit estimates the movable region on the surface of the thumb of the touching hand based on the information on the contact position of the hand, the posture information, and the handle information. Specifically, the movable area estimation unit 220 refers to a pre-stored data table (data table D17 (FIG. 17) defining the relationship between the posture, the handle, the contact area, and the thumb movable area). Then, the movable region on the main surface of the thumb is estimated. In addition, the movable region estimation unit 220 sends information on the hand contact position, posture information, handle information, and information representing the estimated movable region to the communication control unit 230.

  Hereinafter, the estimation process by the movable region estimation unit will be described in detail. FIG. 16 is a diagram for explaining a region of the main surface of the mobile terminal 1A. FIG. 16A is a front view of the mobile terminal 1A. FIG. 16B is a side view of the mobile terminal 1A. Referring to FIG. 16, the region of the main surface is divided (classified) into a plurality of regions α, β, γ, and δ as an example. Each of the regions α, β, γ, and δ is located in this order from the upper end side to the lower end side (operation key 105 side).

  The normals from the feeding points P2 and P3 to the main surface intersect in the region α. That is, the feeding points P2 and P3 are located immediately below the region α in the plurality of regions α to δ. Further, the normal line from the feeding point P1 to the main surface intersects in the region δ. That is, the feeding point P1 is located immediately below the region δ in the plurality of regions α to δ. Below, the movable range in the main surface of the thumb of the hand which the user is holding | maintaining the portable terminal 1A is demonstrated using area | region (alpha), (beta), (gamma), and (delta).

  FIG. 17 is a diagram illustrating a schematic configuration of the data table D17. Referring to FIG. 17, in the data table D17, the posture (vertical, horizontal) of the mobile terminal 1A, the handle of the user's mobile terminal 1A (the hand that is gripping), and the contact area (thumb) on the main surface And the movable range of the thumb on the main surface (that is, the region on the main surface where the thumb can move in the gripping state) is associated with the main surface. The movable area estimation unit 220 refers to the data table D17 and estimates the movable area on the main surface of the thumb.

  Note that the method of dividing the region of the main surface of the mobile terminal 1 (the dividing direction and the number of divisions) is not limited to that shown in FIG. For example, the main surface area may be divided into a matrix. Further, the division method may correspond to the arrangement of the feeding points of the antenna. In these cases, more detailed movable range estimation processing is possible. Note that the data in the data table D17 shown in FIG. 17 needs to be changed according to the method of dividing the main surface area.

  As with the portable terminal 1, the portable terminal 1A has a combination of antennas used for SV-LTE and an antenna used for carrier aggregation so as not to use an antenna having a feeding point that may cover the surface of a nearby casing with a hand. Change each of the combinations. In the mobile terminal 1A, for each estimated movable area, for each communication type (SV-LTE, carrier aggregation), for each band used in each communication type, identification information of the antenna to be used and adjustment of the characteristics of the antenna to be used An antenna switching table (not shown) that associates necessity is stored in advance.

  FIG. 14 is a flowchart showing the flow of processing of the mobile terminal 1A. Referring to FIG. 14, CPU 101 executes steps S102, S104, S106, and S108 instead of steps S8 and S10 in FIG. Further, the CPU 101 executes the process of step S12A instead of step S12.

  In step S102, the CPU 101 receives the coordinate information of the contact position output by each sensor (the back sensor and the plurality of side sensors). In step S104, the CPU 101 detects the grip state based on the received coordinate information. In step S106, the CPU 101 estimates the movable region of the thumb based on the coordinate information. In step S <b> 108, the CPU 101 estimates an antenna whose surface near the feeding point is not covered with a hand, based on the estimated movable region of the thumb. In step S12A, the CPU 101 refers to the antenna switching table described above and selects two antennas to be used.

  In the above description, the movable region estimation unit has been described by taking as an example the configuration in which only the movable region of the thumb is estimated. However, the present invention is not limited to this. The movable region estimation unit may be configured to estimate both the movable region of the thumb and the movable region of fingers other than the thumb. In this case, the CPU 101 uses a combination of antennas used for SV-LTE and carrier aggregation so as not to use an antenna having a feeding point that may cover the surface of a nearby casing with a hand by a thumb and other fingers. Change each combination of antennas used for.

  Even with such a configuration, the portable terminal 1A can suppress degradation of received signal quality as much as possible due to the combination of bands when a plurality of bands are used simultaneously.

(G2. Detection of intermodulation interference)
In the above, the intermodulation wave of a plurality of transmission waves may become an interference wave of any reception wave, and the intermodulation wave of the plurality of transmission waves may become an interference wave of any reception wave The configuration in which the portable terminal 1 stores the combination of bands in advance has been described. However, the present invention is not limited to this, and the mobile terminal 1 determines (detects) whether or not there is a possibility that the intermodulation wave becomes an interference wave of any received wave with respect to the intermodulation wave of a plurality of transmission waves. ). In the case of such a configuration, the mobile terminal 1 may be configured so that, for example, the wireless communication IF 112 includes a detection circuit for detecting intermodulation interference. Note that details of detection of intermodulation interference are disclosed in, for example, a plurality of patent documents (Japanese Patent Laid-Open No. 5-335855, Japanese Patent Laid-Open No. 10-285062, Japanese Patent Laid-Open No. 6-232771, etc.). The description will not be repeated here.

  Further, in the case of the above configuration, in the flowchart shown in FIG. 14, it is determined whether or not intermodulation interference is detected between steps S6 and S8 (hereinafter referred to as “step S7”). ) Is added. The mobile terminal 1 may be configured to proceed to step S8 when it is determined that it is detected in step S7 and to return to step S2 when it is determined that it is not detected in step S7.

  Thus, even in the case of a configuration for determining whether or not there is a possibility of becoming an interference wave, the same effect as when the combination of bands that may become an interference wave is stored in advance is produced. .

(G3. Application to combinations of bands other than the combination of bands that generate interference waves)
In the above description, the configuration in which the combination of antennas to be used is changed is described as an example when the portable terminal 1 uses a combination of bands in which interference waves are generated in each of SV-LTE and carrier aggregation. However, even when a combination of bands that are considered not to generate an interference wave is used, the combination of antennas to be used may be changed and the antenna characteristics may be adjusted as described above.

  The embodiment disclosed this time is an exemplification, and the present invention is not limited to the above contents. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1, 1A mobile terminal, 20 antenna control device, 32 antenna switching table, 33 antenna matching table, 46 variable capacitance element, 101 CPU, 104 flash memory, 108 touch screen, 109 back touch sensor, 110a, 110b, 110c, 110d side Touch sensor, 111 acceleration sensor, 121 first antenna, 122 second antenna, 123 third antenna, 191 to 194 grip sensor, 200 control unit, 210 state detection unit, 220 movable area estimation unit, 230 communication control unit, 231 selection Unit, 240 display control unit, 300 storage unit, 410 antenna switching processing unit, 411 antenna switching device, 420 antenna characteristic adjustment unit, 421 first matching circuit, 422 second matching circuit, 423 third matching circuit, 1081 Spray, 1082 Touch panel, P1, P2, P3 Feed point.

Claims (4)

A portable electronic device,
A plurality of antennas each adapted to wireless communication using individual frequency bands;
Detecting means for detecting a gripping state of the electronic device;
Selection means for selecting two antennas from the plurality of antennas based on the detected gripping state when performing wireless communication using the first frequency band and the second frequency band;
Adjusting means for changing at least one of a resonance frequency and a matching state of the selected antenna when a frequency band suitable for the selected antenna is different from the first frequency band and the second frequency band;
An electronic apparatus comprising: a communication interface that performs wireless communication using the two selected antennas. The adjustment means includes a plurality of matching circuits used for each of a plurality of antennas respectively adapted to wireless communication using the individual frequency bands,
Each of the plurality of matching circuits includes a variable capacitance element,
When the frequency band to which the selected antenna is compatible is different from the first frequency band and the second frequency band, the adjusting means detects the detected grip information to change the characteristics of the selected antenna. The electronic device according to claim 1, wherein a capacitance of the variable capacitance element for the selected antenna is changed based on the parameter.   The adjusting means is arranged so that the impedance of the selected antenna becomes a predetermined value when the frequency band to which the selected antenna is compatible is different from the first frequency band and the second frequency band. The electronic apparatus according to claim 2, wherein a capacitance of the variable capacitance element is changed. Each of the plurality of antennas is built in the electronic device,
The said selection means selects two antennas from which the surface of the said electronic device of the vicinity of the feeding point of the said antenna is not covered with the hand from among these several antennas. The electronic device as described in.

Images