JP2015162018A - Portable terminal, display method and display program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable terminal that instantly determines holding of an enclosure by a user and enables a display object to be displayed at a display position corresponding to a holding style.SOLUTION: A portable terminal has a display part, and has a first antenna disposed in an enclosure in proximity to one lateral wall of a pair of facing lateral walls constituting the enclosure and a second antenna disposed in the enclosure in proximity to the other lateral wall, and the portable terminal comprises: a reflection coefficient measurement unit that measures respective reflection coefficients of the first and second antennas; a determination unit that determines whether the reflection coefficient measured by the reflection coefficient measurement unit is more than a threshold, respectively; a display processing unit that switches a display position of a display object to be displayed in the display part on the basis of a determination result of the determination unit.

Description

  The present invention relates to a mobile terminal provided with a touch panel.

  In a mobile terminal equipped with a touch panel like a so-called smartphone, from the viewpoint of user friendliness, depending on the handle of the user of the mobile terminal, the software keyboard is changed to a position where the user can easily input and displayed. ing. As a technique for determining a handle, Patent Document 1 discloses a technique for detecting a slide operation locus input by a user on a touch panel and determining a handle based on the locus.

JP 2013-80999 A

  However, when the technique of Patent Document 1 is used for the determination of the holding hand, the user does not hold the handheld terminal until the user performs an input to draw a trajectory that can identify the holding hand on the touch panel. There is a problem that the software keyboard cannot be displayed at the display position according to the hand. For this reason, for example, when the user changes the portable terminal from the right hand to the left hand and from the left hand to the right hand, the position where the software keyboard is displayed cannot be changed following the change of the hand.

  The present invention has been made in view of such a problem, and when a casing is gripped by a user, a handle (grip form) is immediately determined, and a display object is displayed at a position corresponding to the handle. An object of the present invention is to provide a portable terminal that can be used.

  In order to solve the above problems, a mobile terminal according to the present invention has a display unit, and a first antenna is disposed in a casing near one of the pair of opposing side walls constituting the casing. A portable terminal in which a second antenna is arranged in a casing near the other side wall, the reflection coefficient measuring unit for measuring the reflection coefficient of each of the first and second antennas, and the reflection coefficient measuring unit A determination unit configured to determine whether or not each of the measured reflection coefficients is equal to or greater than a threshold; and a display processing unit configured to switch a display position of a display object to be displayed on the display unit based on a determination result by the determination unit. .

  Here, as an example, the determination unit and the display processing unit are realized as a function of a control unit including a processor and a memory.

  With the above-described configuration, the mobile terminal according to the present invention changes the reflection coefficient when the user grips the vicinity of the side wall. Therefore, by measuring the reflection coefficient, the display according to whether or not the housing is gripped by the user A display object can be displayed at the position.

The disassembled perspective view which shows an example of the portable terminal which concerns on one embodiment of this invention The top view of the housing | casing by which the antenna was distribute | arranged to the recessed part shown by FIG. (A) It is the figure which looked at the portable terminal from the back, and is a figure which shows an example of the relationship between the holding position of the housing | casing by the user in the case of right-hand holding operation, and the position of an antenna, (b) The figure which looked at the portable terminal from the back FIG. 5 is a diagram illustrating an example of a relationship between a gripping position of a housing by a user and a position of an antenna in the case of a left hand gripping operation, and (c) a view of the mobile terminal as viewed from the back. The figure which shows an example of the relationship between the holding position of the housing | casing by the user when a holding | grip and a right hand operation) are performed, and the position of an antenna The block diagram which shows the function structure of the portable terminal which concerns on embodiment (A) The figure which shows an example of the image which a software keyboard corresponding to right hand holding | grip operation displays on the right side of a display screen (display image), (b) The software keyboard corresponding to left hand holding | grip operation of a display screen The figure which shows an example of the image displayed close to the left side, (c) The figure which shows an example of the image corresponding to a two-hand use operation and displayed without the software keyboard being moved to either the left side or the right side of the display screen (A) A figure showing an example of character input by a right hand grip operation, (b) A figure showing an example of character input by a left hand grip operation, (c) An example of character input by a two-hand use operation (left hand grip, right hand operation as an example) Figure showing The figure which shows an example of the character input image correspondence table Figure showing an example of the measurement result of the reflection coefficient The flowchart which shows an example of the procedure of a character input image display control (A) The figure which shows typically the state of a display in the display part of the portable terminal when the holding | grip of the housing | casing is not carried out by the user when there exists an incoming call based on the modification of this invention, (b) ) The figure which shows typically the display state in the display part of the portable terminal in case the holding | grip of the housing | casing is held by the user based on the modification of this invention. The flowchart which shows an example of the procedure of the display control at the time of an incoming call which concerns on a modification. The top view of the housing | casing by which the antenna was distribute | arranged to the recessed part based on one modification of this invention The block diagram which shows the function structure of the portable terminal based on one modification of this invention The top view of the housing | casing by which the antenna was distribute | arranged to the recessed part based on one modification of this invention

<1. Embodiment>
<1.1. Overview>
Hereinafter, a mobile terminal 1 according to an embodiment of the present invention will be described with reference to the drawings. As shown in FIG. 1, the mobile terminal 1 includes a frame 21 in which a battery 22 and a circuit board 23 are fitted in a space formed by fixing the touch panel 11 in a state of closing the opening of the housing 10. Contained.

  The touch panel 11 includes a liquid crystal display and a touch pad attached so as to cover a display area of the liquid crystal display. The frame 21 is formed using a resin and has a function of holding the battery 22 and the circuit board 23. The battery 22 is composed of a lithium ion battery, and supplies power to each member or component that requires power supply, such as a liquid crystal display, a touch panel, or a circuit element disposed on the circuit board 23. The circuit board 23 is a printed board in which a metal wiring pattern is formed on a board formed using a resin. On the circuit board 23, an electronic circuit group such as a processor, an integrated circuit such as a communication module for performing wireless communication, an imaging device for a camera, a vibration motor, a reflection coefficient measurement IC (Integrated Circuit), a memory, a capacitor, and a coil is arranged. Has been.

  The housing 10 is made of plastic resin, and as shown in FIG. 2, side walls (ASP1 to ASP4) stand up along the outer periphery of the flat plate portion ASP0 having the largest area. On the surface inside the housing of the flat plate portion ASP0, an antenna 13 is formed along the side wall ASP3, and an antenna 14 is formed along the side wall ASP4 facing the side wall ASP3. The user holds the mobile terminal 1 (particularly the housing 10) and operates the touch panel 11. This grip and operation mode (hereinafter referred to as “grip operation mode”) includes a right hand grip operation and a left hand grip. There are three types of operation and two-hand operation. Each of the three types of grip operation modes will be described below. Here, when the user views the mobile terminal 1 from the side (hereinafter referred to as “first surface”) formed by the touch panel 11, the side walls ASP 1, ASP 2, ASP 3, and ASP 4 are respectively located on the upper side, the lower side, Each form will be described on the assumption that the mobile terminal 1 is used in a posture (hereinafter referred to as a “basic posture”) that becomes the left side and the right side.

(A) Right-hand grip operation The right-hand grip operation is a form in which the user grips and operates the mobile terminal 1 with the right hand. In the case of the right hand gripping operation, as shown in FIG. 6A as an example, the user grips the vicinity of the ASP 4 of the mobile terminal 1 with the right hand and operates the touch panel 11 with the thumb of the right hand. When the right hand gripping operation is performed, as shown in FIG. 3A, at least a part of the antenna 14 is seen when the mobile terminal 1 is viewed from the surface (hereinafter referred to as “second surface”) configured by ASP0. Is covered by the user's right hand. On the other hand, the antenna 13 is not covered.

(B) Left-hand grip operation The left-hand grip operation is a form in which the user grips and operates the mobile terminal 1 with the left hand. In the case of the left hand gripping operation, as shown in FIG. 6B, for example, the user grips the vicinity of the ASP 3 of the mobile terminal 1 with the left hand and operates the touch panel 11 with the thumb of the left hand. When the left hand gripping operation is performed, as shown in FIG. 3B, when the mobile terminal 1 is viewed from the second surface side, at least a part of the antenna 13 is covered with the left hand of the user. On the other hand, the antenna 14 is not covered.

(C) Two-hand use operation The two-hand use operation is a form in which the portable terminal 1 is gripped and operated with both hands. In the case of using both hands, the user (i) touches the touch panel 11 with the index finger of the other hand (for example, the right hand) while holding the portable terminal 1 with one hand (for example, the left hand) and the vicinity of ASP3 and ASP4. Or (ii) grip the vicinity of the ASP 4 of the mobile terminal 1 with the right hand, grip the vicinity of the ASP 3 with the left hand, and operate the touch panel 11 with the thumb of at least one hand. When the two-hand use operation is performed, as shown in FIG. 6C as an example, when the mobile terminal 1 is viewed from the second surface side, at least part of the antenna 13 and at least part of the antenna 14 are both users. Covered by hands.

Here, if the antennas (13, 14) are covered by the user's hand, the covered antenna and the human body are capacitively coupled, and therefore, the resonance frequency of the covered antenna is shifted, and the antenna is covered. The reflection coefficient of the broken antenna increases. Here, the reflection coefficient is a ratio between the magnitude of the traveling wave input to the antenna and the magnitude of the reflected wave reflected from the antenna when the resonance frequency is shifted. The mobile terminal 1 measures the reflection coefficient of each antenna, determines how the user holds the housing using the reflection coefficient, and performs processing according to the specified holding method to improve user convenience. ing.
<1.2. Configuration>
As shown in FIG. 4, the mobile terminal 1 has a display unit 12, an antenna 13, an antenna 14, a transmission / reception unit 401, a circulator 402, a reflection coefficient measurement unit 403, a bidirectional coupler 404, a transmission / reception unit 411. A circulator 412, a reflection coefficient measurement unit 413, a bidirectional coupler 414, a control unit 421, an input unit 431, a storage unit 432, and a notification unit 433.

The display unit 12 is realized by the above-described liquid crystal display and has a function of displaying an image or the like in a display area. The display unit 12 has a function of turning on and off a backlight of the liquid crystal display. Whether the backlight is turned on or off is instructed by the control unit 421.
The input unit 431 is realized by the touch pad described above, and has a function of detecting a contact operation by a user based on a change in capacitance and outputting a detection signal representing the contact operation to the control unit 421. The input unit 431 is used by the user to input an instruction such as moving a cursor displayed on the liquid crystal display or selecting a display object such as an icon.

  The antenna 13 is a flat antenna for performing wireless communication using radio waves of a predetermined frequency band (800 MHz band as an example). The electrical length of the antenna 13 is ¼ wavelength of the radio wave used for wireless communication. The antenna 13 is located at a position where the reflection coefficient changes when at least a part of the antenna 13 is covered with the right hand of the user when the mobile terminal 1 is operated to hold or use both hands by the user (see FIG. 2). It is arranged.

  The antenna 14 is a flat antenna for performing wireless communication using radio waves in a predetermined frequency band (2 GHz band as an example). The electrical length of the antenna 14 is ¼ wavelength of radio waves used for wireless communication. The antenna 14 is arranged at a position (see FIG. 2) where the reflection coefficient changes when the mobile terminal 1 is gripped or used with both hands by the user and at least part of the antenna 14 is covered with the left hand of the user. Has been.

  The transmission / reception unit 401 is realized by an LSI for wireless communication, and has a function of performing wireless communication with a communication partner such as a base station or an access point using the antenna 13. The transmission / reception unit 401 performs wireless communication using the 800 MHz band as a frequency band. The transmission / reception unit 401 includes a signal transmission terminal (TX1) and a signal reception terminal (RX1). When receiving a transmission instruction including transmission data from the control unit 421, the transmission / reception unit 401 generates a transmission signal by modulating a carrier wave based on the received transmission data. And the transmission / reception part 401 outputs the produced | generated transmission signal from TX1. Further, when receiving the reception signal received by the antenna 13 and input to the RX 1, the transmission / reception unit 401 reconstructs the reception data by demodulating the received reception signal, and outputs the reconstructed reception data to the control unit 421. To do.

In addition, the transmission / reception unit 401 has a carrier wave output function. When receiving a reflection coefficient measurement start instruction from the control unit 421 as a process related to the carrier wave output function, the transmission / reception unit 401 uses an 800 MHz band carrier wave as a traveling wave for measuring the reflection coefficient for a predetermined carrier transmission period. In the meantime, it outputs from TX1. When receiving the reflection coefficient measurement stop instruction, the output of the carrier wave from TX1 is stopped. The carrier wave transmission period need only be long enough to allow the reflection coefficient measurement unit 403 to measure the reflection coefficient. The carrier transmission period is, for example, a length corresponding to 10 carrier cycles.
The carrier power used when executing the carrier wave output function is sufficient if the reflection coefficient can be measured by the reflection coefficient measurement unit 403, and the carrier wave power used when communicating with a communication partner such as a base station or an access point is sufficient. What is very small compared with electric power (for example, about 1/10) may be sufficient. Since the measurement of the reflection coefficient requires less power than during communication, power consumption can be suppressed.

Further, the transmission / reception unit 401 has a function of measuring RSSI (reception signal strength) of a reception signal received by the antenna 13.
The circulator 402 is realized by a circulator element having three ports (PA1, PB1, PC1). The circulator 402 allows a signal input to a certain port to pass only to a specific port. Specifically, circulator 402 outputs a signal input to PA1 only to PB1, outputs a signal input to PB1 only to PC1, and outputs a signal input to PC1 only to PA1.

  PA1 is connected to OP1 of bidirectional coupler 404 as shown in FIG. PB1 is connected to the antenna 13. PC1 is connected to the reception signal input terminal (RX1) of the transceiver 401. In principle, the circulator 402 does not pass any signal from PB1 to PA1, PC1 to PB1, and PA1 to PC1, but the reflected wave generated by the antenna 13 is output through PB1 and PA1.

  A traveling wave output from TX1 of the transmission / reception unit 401 when measuring the reflection coefficient is input to PA1 via the bidirectional coupler 404. The traveling wave input to PA1 is output from PB1 to antenna 13. When a reflected wave is generated with respect to the traveling wave input to the antenna 13, the reflected wave is output to OP1 of the bidirectional coupler 404 via PB1 and PA1.

  The reflection coefficient measurement unit 403 is realized by a reflection coefficient measurement IC having a function of measuring the reflection coefficient. The reflection coefficient measurement unit 403 includes a traveling wave input terminal (INF1) and a reflected wave input terminal (INR1). A traveling wave output from CP1 of the bidirectional coupler 404 is input to INF1. In addition, a reflected wave from the antenna 13 output from CP2 of the bidirectional coupler 404 is input to INR1. Here, the signal output from CP1 of bidirectional coupler 404 is actually not a traveling wave itself, but a magnitude of a certain ratio (for example, 1/100) of the traveling wave, as will be described later. Signal. Also, the signal output from CP2 of the bidirectional coupler 404 is not a reflected wave itself but a signal having a magnitude of a certain ratio (for example, 1/100) of the reflected wave. However, in this specification, for the sake of convenience, a signal having a certain ratio of traveling wave input to the reflection coefficient measurement unit 403 is also expressed as “traveling wave” unless it is particularly necessary to distinguish between them. A signal having a certain ratio of the reflected wave input to the reflection coefficient measuring unit 403 is also expressed as “reflected wave”.

  When receiving the reflection coefficient measurement instruction from the control unit 421, the reflection coefficient measurement unit 403 measures the effective value (Vf1) of the traveling wave voltage input from the INF1 during a predetermined measurement period. In addition, the effective value (Vr1) of the voltage of the reflected wave input from INR1 is measured for a predetermined period. Then, the reflection coefficient measurement unit 403 calculates the reflection coefficient RE1 (= Vf1 / Vr1) of the antenna 13 using Vf1 and Vr1, and outputs the calculated reflection coefficient RE1 to the control unit 421. The reflection coefficient measurement unit 403 measures the reflection coefficient within a period in which the traveling wave transmitted from the transmission / reception unit 401 is input to INF1 and the reflected wave with respect to the traveling wave is input to INR1.

  The bidirectional coupler 404 is a bidirectional coupler having four ports (IP1, OP1, CP1, CP2). Bidirectional coupler 404 has a function of outputting a signal input to IP1 from OP1 and also outputting from CP1 at a constant rate. In addition, the bidirectional coupler 404 has a function of outputting a signal input to OP1 from IP1 and also from CP2 at a constant rate. Here, the fixed ratio is, for example, 1/100. IP1 is connected to TX1, OP1 is connected to PA1, CP1 is connected to INF1, and CP2 is connected to INR1.

  The transmission / reception unit 411 is realized by an LSI for wireless communication, and has a function of performing wireless communication with a communication partner such as a base station or an access point using the antenna 14. The transmission / reception unit 411 performs wireless communication using a 2 GHz band as a frequency band. The transmission / reception unit 411 includes a signal transmission terminal (TX2) and a signal reception terminal (RX2). When receiving a transmission instruction including transmission data from the control unit 421, the transmission / reception unit 411 generates a transmission signal by modulating a carrier wave based on the received transmission data. And the transmission / reception part 411 outputs the produced | generated transmission signal from TX2. Further, when receiving the reception signal received by the antenna 14 and input to the RX 2, the transmission / reception unit 411 restores the reception data by demodulating the received reception signal, and outputs the restored reception data to the control unit 421. To do.

  The transmission / reception unit 411 has a carrier wave output function. As a process related to the carrier wave output function, the transmission / reception unit 411 receives a 2 GHz band carrier wave for a predetermined carrier wave transmission period as a traveling wave for measuring the reflection coefficient when receiving a reflection coefficient measurement start instruction from the control unit 421. In the meantime, it outputs from TX2. When the reflection coefficient measurement stop instruction is received, the output of the carrier wave from TX2 is stopped. The carrier wave transmission period need only be long enough to allow the reflection coefficient measurement unit 413 to measure the reflection coefficient. The carrier transmission period is, for example, a length corresponding to 10 carrier cycles. In addition, the power of the carrier wave used when executing the carrier wave output function is sufficient if the reflection coefficient measurement unit 413 can measure the reflection coefficient, and the carrier wave power used when communicating with a communication partner such as a base station or an access point is sufficient. What is very small compared with electric power (for example, about 1/10) may be sufficient. Since the measurement of the reflection coefficient requires less power than during communication, power consumption can be suppressed.

Further, the transmission / reception unit 411 has a function of measuring the RSSI of the reception signal received by the antenna 14.
The circulator 412 is realized by a circulator element having three ports (PA2, PB2, PC2). The circulator 412 allows a signal input to a certain port to pass only to a specific port. Specifically, circulator 412 outputs the signal input to PA2 only to PB2, outputs the signal input to PB2 only to PC2, and outputs the signal input to PC2 only to PA2.

  PA2 is connected to OP2 of bidirectional coupler 414 as shown in FIG. PB2 is connected to antenna 14. PC2 is connected to the reception signal input terminal (RX2) of the transmission / reception unit 411. In principle, the circulator 412 does not pass any signal from PB2 to PA2, PC2 to PB2, and PA2 to PC2, but the reflected wave generated by the antenna 14 is output through PB2 and PA2.

  A traveling wave output from TX2 of the transmission / reception unit 411 when measuring the reflection coefficient is input to PA2 via the bidirectional coupler 414. The traveling wave input to PA2 is output from PB2 to antenna 14. When a reflected wave is generated with respect to the traveling wave input to the antenna 14, the reflected wave is output to OP1 of the bidirectional coupler 414 via PB2 and PA2.

  The reflection coefficient measurement unit 413 is realized by a reflection coefficient measurement IC having a function of measuring the reflection coefficient. The reflection coefficient measurement unit 413 has a traveling wave input terminal (INF2) and a reflected wave input terminal (INR2). A traveling wave output from CP3 of the bidirectional coupler 414 is input to INF2. Moreover, the reflected wave from the antenna 14 output from the CP4 of the bidirectional coupler 414 is input to the INR2. Here, the signal output from the CP3 of the bidirectional coupler 414 is actually not a traveling wave itself, but a magnitude of a certain proportion (for example, 1/100) of the traveling wave, as will be described later. Signal. Further, the signal output from CP4 of the bidirectional coupler 414 is not a reflected wave itself but a signal having a magnitude of a certain ratio (for example, 1/100) of the reflected wave. However, in this specification, for the sake of convenience, a signal having a certain proportion of traveling wave input to the reflection coefficient measurement unit 413 is also expressed as “traveling wave” unless it is particularly necessary to distinguish between them. A signal having a certain ratio of the reflected wave input to the reflection coefficient measuring unit 413 is also expressed as “reflected wave”.

  When the reflection coefficient measurement unit 413 receives the reflection coefficient measurement instruction from the control unit 421, the reflection coefficient measurement unit 413 measures the effective value (Vf2) of the traveling wave voltage input from the INF2 during a predetermined measurement period. Further, the effective value (Vr2) of the voltage of the reflected wave input from INR2 is measured for a predetermined period. Then, the reflection coefficient measurement unit 413 calculates the reflection coefficient RE2 (= Vf2 / Vr2) of the antenna 14 using Vf2 and Vr2, and outputs the calculated reflection coefficient RE2 to the control unit 421. The reflection coefficient measurement unit 413 measures the reflection coefficient within a period in which the traveling wave transmitted from the transmission / reception unit 411 is input to the INF2 and the reflected wave with respect to the traveling wave is input to the INR2.

  The bidirectional coupler 414 is a bidirectional coupler having four ports (IP2, OP2, CP3, CP4). Bidirectional coupler 414 has a function of outputting a signal input to IP2 from OP2 and also from CP3 at a constant rate. In addition, the bidirectional coupler 414 has a function of outputting a signal input to OP2 from IP2 and also from CP4 at a constant rate. Here, the fixed ratio is, for example, 1/100. IP2 is connected to TX2, OP2 is connected to PA2, CP3 is connected to INF2, and CP4 is connected to INR2.

  The storage unit 432 is realized by a non-volatile memory such as FeRAM (Ferroelectric Random Access Memory) and has a function of holding data. The storage unit 432 holds information necessary for the mobile terminal 1 to operate. For example, the storage unit 432 holds address book information, data for generating an image to be displayed on the display unit 12, a character input image correspondence table, and the like.

The address book information is information that describes a telephone number and a name in association with each other.
Data for generating an image includes an object constituting a part of a frame image, such as a software keyboard image 501 (see FIGS. 5A to 5C).
As shown in FIG. 7, the character input image correspondence table is a table showing the correspondence between the grip operation modes and the character input images to be displayed on the display unit 12 corresponding to the grip operation modes. In the character input image correspondence table, the grip operation mode is represented by a set (LH, RH) of a variable LH and a variable RH. The variable LH represents whether or not the housing 10 is covered with the user's left hand. When the value of the variable LH is 1, it indicates that the housing 10 is covered with the user's left hand. When the value of the variable LH is 0, it indicates that the housing 10 is not covered with the left hand of the user. The variable RH represents whether or not the housing 10 is covered with the user's right hand. When the value of the variable RH is 1, it indicates that the housing 10 is covered with the user's right hand. When the value of the variable RH is 0, it indicates that the housing 10 is not covered with the user's right hand.

  When (LH, RH) is (0, 1), it represents a right hand grip operation. The character input image associated with (0, 1) is an R image 511 shown in FIG. In the R image 511, a software keyboard image 501 that is touched when inputting characters so that the user can easily input characters with the thumb of the right hand in the case of a right hand grip operation is displayed on the side (box) near the right hand of the R image 511. This is a frame image brought close to the ASP4 side of the body 10.

  When (LH, RH) is (1, 0), it represents a left hand gripping operation. The character input image associated with (1,0) is an L image 512 shown in FIG. The L image 512 brings the software keyboard image 501 close to the side of the L image 512 close to the left hand (corresponding to the ASP 3 side of the housing 10) so that the user can easily input characters with the thumb of the left hand in the case of the left hand grip operation. It is a frame image.

When (LH, RH) is (1, 1), it represents a two-handed use operation. The character input image associated with (1,1) is a B image 513 shown in FIG. The B image 513 is a frame image in which the software keyboard image 501 is arranged at the lower center of the B image so that the user can easily input characters when using both hands.
When (LH, RH) is (0, 0), the mobile terminal 1 is not held by the user. B image 513 as a default character input image is associated with (0, 0).

The notification unit 433 includes a vibration motor and has a vibration function that vibrates when receiving a vibration instruction from the control unit 421. When the notification unit 433 executes the vibration function, the entire mobile terminal 1 vibrates. The vibration function is used to notify the user that an incoming call has occurred.
The timer unit 434 includes a real time clock IC and has a function of measuring time and time.

The control unit 421 includes a processor and a memory, and has a function of controlling the overall operation of the mobile terminal 1. Here, each function which the control part 421 has is implement | achieved when a processor runs the program memorize | stored in memory. The control unit 421 has a reflection coefficient acquisition function, a gripping state determination function, and a display processing function as main functions. Each function will be described below.
(A) Reflection coefficient acquisition function The reflection coefficient acquisition function is a function for acquiring the reflection coefficient RE1 of the antenna 13 and the reflection coefficient RE2 of the antenna 14. The control unit 421 controls the transmission / reception unit 401, the transmission / reception unit 411, the reflection coefficient measurement unit 403, and the reflection coefficient measurement unit 413 to acquire RE1 and RE2 (steps S903 and S904 in FIG. 9).
(B) Grasping state determination function The gripping state determination function is a function for determining whether or not the casing is gripped by the user based on RE1 and RE2, and for determining the gripping operation mode when gripped ( Step S902 of FIG. 9, step S904-step S906, step S908-step S915).
(C) Display processing function The display processing function is a function that generates an image such as a character input image according to the result determined by the gripping state determination function and displays the image on the display unit 12 (step S913 in FIG. 9). S915).
<1.3. Study on Threshold Used by Control Unit 421>
FIG. 8 shows results of actually measuring the reflection coefficient of the antenna when the casing is gripped (the antenna is covered by a human body) and when the casing is not gripped.

When the frequency of the radio wave used by the antenna is 800 MHz, the reflection coefficient when the housing is not gripped is 0.26. When the housing is gripped, the reflection coefficient increases to 0.74. As the threshold TH1, 0.5, which is an intermediate value between the reflection coefficient when gripping and the reflection coefficient when gripping is not used.
When the frequency of the radio wave used by the antenna is 2 GHz, the reflection coefficient when the housing is not gripped is 0.07. When the housing is gripped, the reflection coefficient increases to 0.42. As the threshold value TH2, 0.25 which is an intermediate value between the reflection coefficient when the grip is present and the reflection coefficient when the grip is not present is used. As described above, since the reflection coefficient of the antenna differs for each frequency band used by the antenna, a different value is used for the threshold value for each frequency band.
<1.4. Operation>
A character input image display process executed by the mobile terminal 1 configured as described above will be described.

  First, in step S <b> 901, the user inputs a character input image display instruction using the input unit 431. For example, the display instruction of the character input image is performed by the user touching an icon that is displayed on the display unit 12 and instructing the start of character input. When the input unit 431 detects that an icon for instructing start of character input is touched, the input unit 431 outputs a character input image display instruction to the control unit 421 as a detection signal. The control unit 421 acquires a character input image display instruction.

  In step S902, the control unit 421 initializes the variables LH and RH with the value 0. When the value of the variable LH is 1, it indicates that at least a part of the ASP 3 is covered by the user's hand, and when the value is 0, the vicinity of the ASP 3 is not held by the user. Indicates. The variable RH indicates that when the value is 1, the user's hand is gripped so that at least a part of the ASP 4 is covered. When the value is 0, the vicinity of the ASP 4 is not gripped by the user. It shows that.

In step S903, the control unit 421 transmits a reflection coefficient measurement start instruction to the transmission / reception unit 401, the reflection coefficient measurement unit 403, the transmission / reception unit 411, and the reflection coefficient measurement unit 413.
When receiving the reflection coefficient measurement start instruction, the transmission / reception unit 401 outputs the carrier wave from TX1 as a traveling wave by the carrier wave output function. The traveling wave is input to PA1 of circulator 402 through IP1 and OP1 of bidirectional coupler 404, and is output from PB1 to antenna 13. Further, the traveling wave is input to INF1 of the reflection coefficient measuring unit 403 through IP1 and CP1 of the bidirectional coupler 404. When a reflected wave with respect to the traveling wave is generated in the antenna 13, the reflected wave is output to OP1 of the bidirectional coupler 404 via PB1 and PA1. The reflected wave output from PA1 is input to INR1 of reflection coefficient measuring unit 403 through OP1 and CP2 of bidirectional coupler 404. The reflection coefficient measurement unit 403 measures the effective value (Vf1) of the traveling wave voltage input from the INF1. The reflection coefficient measuring unit 403 measures the effective value (Vr1) of the voltage of the reflected wave input from INR1. Then, the reflection coefficient measurement unit 403 calculates the reflection coefficient RE1 of the antenna 13 using Vf1 and Vr1, and outputs the calculated reflection coefficient RE1 to the control unit 421.

  In step S904, the control unit 421 receives the reflection coefficient RE1 output from the reflection coefficient measurement unit 403. The control unit 421 determines whether or not the received reflection coefficient RE1 is greater than or equal to the first threshold value (TH1). When the control unit 421 determines that the reflection coefficient RE1 is greater than or equal to TH1 (YES in step S904), the control unit 421 substitutes 1 for the variable lh (step S905). When the control unit 421 determines that the reflection coefficient RE1 is less than TH1 (NO in step S904), the control unit 421 substitutes 0 for the variable lh (step S906).

  In step S907, when the transmission / reception unit 411 receives the reflection coefficient measurement start instruction, the transmission / reception unit 411 outputs the carrier wave from TX2 as a traveling wave by the carrier wave output function. The traveling wave is input to PA2 of circulator 412 through IP2 and OP2 of bidirectional coupler 414, and is output from PB2 to antenna 14. The traveling wave is input to INF2 of the reflection coefficient measuring unit 413 through IP2 and CP3 of the bidirectional coupler 414. When a reflected wave with respect to the traveling wave is generated in the antenna 14, the reflected wave is output to OP2 of the bidirectional coupler 414 via PB2 and PA2. The reflected wave output from PA2 is input to INR2 of reflection coefficient measuring unit 413 through OP2 and CP4 of bidirectional coupler 414. The reflection coefficient measurement unit 413 measures the effective value (Vf2) of the traveling wave voltage input from the INF2. Further, the reflection coefficient measurement unit 413 measures the effective value (Vr2) of the voltage of the reflected wave input from INR2. Then, the reflection coefficient measurement unit 413 calculates the reflection coefficient RE2 of the antenna 13 using Vf2 and Vr2, and outputs the calculated reflection coefficient RE2 to the control unit 421.

  In step S908, the control unit 421 receives the reflection coefficient RE2 output from the reflection coefficient measurement unit 413. The control unit 421 determines whether or not the received reflection coefficient RE2 is greater than or equal to the second threshold value (TH2). If the control unit 421 determines that the reflection coefficient RE2 is greater than or equal to TH2 (YES in step S908), the control unit 421 substitutes 1 for the variable rh (step S909). If the control unit 421 determines that the reflection coefficient RE2 is less than TH2 (NO in step S908), the control unit 421 substitutes 0 for the variable rh (step S910).

Here, step S903 to step S910 in FIG. 9 are described as a sequential process in which the reflection coefficient measurement unit 403 measures RE1 and then the reflection coefficient measurement unit 413 measures RE2. However, the measurement of RE1 and the measurement of RE2 can be performed in parallel, and may be performed in parallel.
In step S911, the control unit 421 determines whether LH and lh match and RH and rh match. If they match (YES in step S911), the process proceeds to step S914. If they do not match (NO in step S911), the process proceeds to step S912.

In step S912, the control unit 421 substitutes the value of the variable lh for the variable LH, and substitutes the value of the variable rh for the variable RH.
In step S <b> 913, the control unit 421 refers to the character input image correspondence table stored in the storage unit 432. Then, the control unit 421 generates a character input image associated with (LH, RH) in the character input image correspondence table using an object such as the software keyboard image 501 stored in the storage unit 432. . Then, the control unit 421 outputs a signal representing the generated character input image to the display unit 12. The display unit 12 receives a signal representing a character input image and displays the character input image in the display area.

  In step S914, the control unit 421 determines whether or not an instruction to stop displaying the character input image has been issued. The instruction to stop displaying the character input image is performed, for example, when the user touches an icon (not shown) that is displayed on the display unit 12 and instructs to stop the character input. The control unit 421 determines whether or not a character input image display stop instruction has been issued based on whether or not a detection signal indicating a character input image display stop instruction has been received from the input unit 431.

  In step S915, upon receiving a character input image display stop instruction, the control unit 421 transmits a character input image display stop instruction to the display unit. The display unit 12 stops displaying the character input image displayed in the display area. In addition, the control unit 421 instructs the transmission / reception unit 401 and the transmission / reception unit 411 to stop execution of the carrier wave output function. The transmission / reception unit 401 and the transmission / reception unit 411 stop executing the carrier wave output function. In addition, the control unit 421 outputs a reflection coefficient measurement stop instruction to the reflection coefficient measurement unit 403 and the reflection coefficient measurement unit 413. When the reflection coefficient measurement unit 403 and the reflection coefficient measurement unit 413 receive a reflection coefficient measurement stop instruction, the reflection coefficient measurement unit 403 stops measuring the reflection coefficient.

  As described above, the mobile terminal 1 determines the gripping operation mode by measuring a reflection coefficient using a carrier wave generated in the mobile terminal 1 (transmission / reception units 401 and 411) as a traveling wave. Therefore, the portable terminal 1 can determine the grip operation mode even in a place where the antennas 13 and 14 cannot receive radio waves. In addition, when the user performs character input, the mobile terminal 1 determines the grip operation mode even if the user does not input to the touch panel 11, and the user inputs a software keyboard according to the grip operation mode. Can be immediately displayed at a position where it is easy to perform.

<2. Modification>
The embodiment of the mobile terminal according to the present invention has been described above. However, the illustrated mobile terminal can be modified as follows, and the present invention is applied to the mobile terminal as shown in the above-described embodiment. Of course, it is not limited.
(1) In the above-described embodiment, two components of the reflection coefficient measurement unit 403 and the reflection coefficient measurement unit 413 are used to measure the reflection coefficient. However, it is sufficient if the reflection coefficients of all the antennas can be measured. . For example, the reflection coefficient of a plurality of antennas may be measured by one reflection coefficient measurement unit. In this case, as an example, the traveling wave input terminal of one reflection coefficient measuring unit is connected so that the traveling wave applied to each antenna is input, and the reflected wave input terminal of the reflected wave coefficient measuring unit is connected to each antenna. Connect so that the reflected wave that is generated is input. And the transmission / reception part 401 and the transmission / reception part 411 perform a carrier wave output function alternately for every time slice of predetermined time length, and output a traveling wave. In a certain time slice, the traveling wave output from the transmission / reception unit 401 to the antenna 13 is input to the traveling wave input terminal of the reflected wave coefficient measurement unit, and the reflected wave from the antenna 13 is input to the traveling wave input terminal. In this time slice, the reflected wave coefficient measurement unit measures RE1. In the next time slice, the traveling wave output from the transmission / reception unit 411 to the antenna 13 is input to the traveling wave input terminal of the reflected wave coefficient measurement unit, and the reflected wave from the antenna 14 is input to the traveling wave input terminal. . In this time slice, the reflected wave coefficient measurement unit measures RE2.

(2) In the above embodiment, the reflection coefficient of the antenna 13 and the reflection coefficient of the antenna 14 are used to determine the grip operation mode. However, the present invention may be applied to the determination of whether or not the casing is being gripped by the user without determining the grip operation mode.
Below, an example of the portable terminal 1a which changes the process which concerns on a display according to whether the housing | casing is hold | gripped by the user is demonstrated. The functional configuration of the mobile terminal 1a is the same as the functional configuration of the mobile terminal 1 shown in FIG. 4 except that the control content by the control unit 421 is different. Therefore, illustration of the functional configuration of the portable terminal 1a is omitted.

  When the mobile terminal 1a according to the present modification receives an incoming call and the user does not hold the casing 10 of the mobile terminal 1a, the mobile terminal 1a performs notification by vibration as shown in FIG. The backlight of 12 is turned off to save power. On the other hand, when the user is holding the casing 10, as shown in FIG. 10 (b), notification by vibration is performed, and the backlight of the display unit 12 is turned on, so that information related to the incoming call to the user is displayed. An incoming image 1002 including (there is an incoming call, the name of the caller) is presented.

Hereinafter, an example of the incoming call display control process including the process of determining whether or not the user holds the casing using the reflection coefficient by the mobile terminal 1a will be described with reference to FIG.
In step S1101, the transmission / reception unit 401 receives the incoming call signal from the base station via the antenna 13 or the transmission / reception unit 411 via the antenna 14. The transmission / reception unit 401 or the transmission / reception unit 411 transmits a display notification start trigger to the control unit 421 when receiving the incoming call signal. The display notification start trigger includes the telephone number of the partner terminal that has requested communication with the portable terminal 1a, which is included in the incoming call signal. The control unit 421 acquires a display notification start trigger.

In step S1102, the control unit 421 substitutes the value 2 for the variable DISP. Here, if the value of the variable DISP is 2, it indicates that it has not been determined whether or not the housing is gripped. A value of 1 indicates that the housing is gripped, and a value of 0 indicates that the housing is not gripped.
In step S1103, the control unit 421 substitutes the value 1 for the variable i.

  In step S1104, the control unit 421 acquires a reflection coefficient REi (RE1 when i is 1, RE2 when i is 2). Here, when i = 1, the process performed in step S1104 is the same process as step S903 in FIG. 9 for obtaining RE1. When i = 2, the process performed in step S1104 is the same process as step S907 in FIG. 9 for acquiring RE2.

  In step S1105, the control unit 421 determines whether or not the reflection coefficient REi is greater than or equal to a threshold value THi (TH1 when i is 1, TH2 when i is 2). If it is determined that the reflection coefficient REi is greater than or equal to THi (YES in step S1105), the control unit 421 substitutes 1 for the variable disp (step S1109) and proceeds to step S1110. Here, the variable disp indicates that the housing is gripped when the value is 1, and indicates that the housing is not gripped when the value is 0.

  When it is determined that the reflection coefficient REi is less than THi (NO in step S1105), the control unit 421 increases the value of the variable i by 1 (step S1106). Then, it is determined whether or not the variable i is larger than the number of antennas (2 in this modification) (step S1109). If i is equal to or less than the number of antennas (NO in step S1107), the process proceeds to step S1104. When i is larger than the number of antennas (YES in step S1107), the control unit 421 substitutes 0 for the variable disp (step S1108), and proceeds to step S1110.

In step S1110, the control unit 421 determines whether or not the values of the variable DISP and the variable disp match. If it is determined that they match (YES in step S1110), the process proceeds to step S1116. If it is determined that they do not match (NO in step S1110), the process proceeds to step S1111.
In step S1111, the control unit 421 substitutes the value of the variable disp for the variable DISP.

In step S1112, the control unit 421 determines whether the DISP value is 1. If DISP is 1 (YES in step S1112), the process proceeds to step S1113. If DISP is 0 (NO in step S1112), the process proceeds to step S1115.
In step S1113, the control unit 421 instructs the display unit 12 to turn on the backlight. When the display unit 12 receives the instruction, the display unit 12 turns on the backlight.

  In step S1114, the control unit 421 reads the name corresponding to the telephone number included in the display notification start trigger from the address book. Then, an incoming image 1002 including a panel 1001 indicating “incoming” and “read name” is generated, and a signal representing the incoming image 1002 is output to the display unit 12. The display unit 12 receives a signal representing the incoming image 1002 and displays the incoming image 1002 based on the received signal.

In step S1115, the control unit 421 instructs the display unit 12 to turn off the backlight. The display unit 12 turns off the backlight when receiving the instruction.
In step S1116, the control unit 421 determines whether to stop the display notification. The control unit 421 inputs (a) an instruction for the user to answer an incoming call using the input unit 431 (for example, the user touches an off-hook icon (not shown) displayed on the display unit 12). It is determined that the display notification is stopped when a predetermined notification time has elapsed since the acquisition of the display notification start trigger.

If the control unit 421 determines not to stop the display notification (NO in step S1116), the process proceeds to step S1103.
When the control unit 421 determines to stop the display notification (YES in step S1116), the process proceeds to step S1117.
In step S1117, the control unit 421 instructs the display unit 12 to stop displaying the incoming image 1002. The display unit 12 stops displaying the incoming image 1002.

With the above control, when there is an incoming call, the mobile terminal 1 displays the incoming call image 1002 when the casing 10 is gripped by the user, and the backlight is turned off when the casing 10 is not gripped. .
As described above, according to the mobile terminal according to the present modification, whether or not the housing is held by the user can be realized with a simple configuration of measuring the reflection coefficient of the antenna.

  (3) In the above-described embodiment and each modification, the antenna having the shape shown in FIG. 2 is used as an example. However, the user holds the casing by a change in the reflection coefficient of the antenna arranged in the casing. If it can be detected, the size, length, shape, etc. of the antenna are not limited. For example, as shown in FIG. 12, the antennas 13 and 14 may be arranged so that the antennas 13 and 14 form a substantially rectangular annular shape along the outer periphery of the ASP0. If it does in this way, even if the user did the way of gripping which covers any of the side walls ASP1 to ASP4 of the housing 10, it can be detected that it has been gripped.

(4) In the above-described embodiment and modification, the gripping of the housing 10 by the user is detected using the reflection coefficients of the two antennas. However, the reflection coefficient of one or three or more antennas is detected. It is good also as using.
Hereinafter, as an example, a portable terminal 1b that detects whether or not the user holds the casing 10 by using four antennas will be described as an example.

In the portable terminal 1b, as shown in FIG. 12, the antennas ANT1 to ANT4 are arranged on the ASP0 so as to form a substantially rectangular ring along the outer periphery of the ASP0.
As shown in FIG. 13, the mobile terminal 1 b has a functional configuration in addition to the configuration of the mobile terminal 1 of FIG. 4, an antenna 1300, a transmission / reception unit 1301, a circulator 1302, a reflection coefficient measurement unit 1303, a bidirectional coupler 1304. , Antenna 1310, transmission / reception unit 1311, circulator 1312, reflection coefficient measurement unit 1313, and bidirectional coupler 1314.

The functions of the antenna 1300, the transmission / reception unit 1301, the circulator 1302, the reflection coefficient measurement unit 1303, and the bidirectional coupler 1304 are the antenna 13, the transmission / reception unit 401, the circulator 402, the reflection coefficient measurement unit 403, and the bidirectionality, respectively. The function is similar to that of the coupler 404.
The reflection coefficient RE3 of the antenna 1300 can be measured as follows. That is, when the transmission / reception unit 1301 outputs a carrier wave as a traveling wave by executing the carrier wave output function, the traveling wave passes through the bidirectional coupler 1304 to the traveling wave input terminal of the reflection coefficient measurement unit 1303 or The signal is input to the antenna 1300 via the bidirectional coupler 1304 and the circulator 1302. When a reflected wave is generated in the antenna 1300, the reflected wave is input to the reflected wave input terminal of the reflection coefficient measuring unit 1303 via the circulator 1302 and the bidirectional coupler 1304.

The reflection coefficient measurement unit 1303 measures the effective value (Vf3) of the traveling wave voltage input to the traveling wave input terminal, and measures the effective value (Vr3) of the reflected wave voltage input to the reflected wave input terminal. . Then, the reflection coefficient RE3 (= Vf3 / Vr3) of the antenna 1300 is calculated using Vf3 and Vr3, and the calculated reflection coefficient RE3 is output to the control unit 421.
When control unit 421 receives RE3, control unit 421 determines whether RE3 is equal to or greater than a predetermined threshold value TH3. When RE3 is greater than or equal to TH3, it is estimated that the housing 10 is gripped so that the antenna 1300 is covered by the user.

  Also, the reflection coefficient RE4 of the antenna 1310 can be measured as follows. That is, when the transmitting / receiving unit 1311 outputs a carrier wave as a traveling wave by executing the carrier wave output function, the traveling wave is transmitted to the traveling wave input terminal of the reflection coefficient measuring unit 1313 via the bidirectional coupler 1314 or The signal is input to the antenna 1310 via the bidirectional coupler 1314 and the circulator 1312. When a reflected wave is generated at the antenna 1310, the reflected wave is input to the reflected wave input terminal of the reflection coefficient measuring unit 1313 via the circulator 1312 and the bidirectional coupler 1314.

The reflection coefficient measurement unit 1313 measures the effective value (Vf4) of the traveling wave voltage input to the traveling wave input terminal, and measures the effective value (Vr4) of the reflected wave voltage input to the reflected wave input terminal. . Then, the reflection coefficient RE4 (= Vf4 / Vr4) of the antenna 1310 is calculated using Vf4 and Vr4, and the calculated reflection coefficient RE4 is output to the control unit 421.
When receiving the RE4, the control unit 421 determines whether RE4 is equal to or greater than a predetermined threshold TH4. When RE4 is equal to or higher than TH4, it is estimated that the user holds the housing 10 so that the antenna 1310 is covered.

  Here, even when the reflection coefficients RE1 to RE4 measured for the antennas 13, 14, 1300, and 1310 are used, it is detected whether or not the user holds the casing 10 by the procedure shown in the flowchart of FIG. can do. In this case, the “number of antennas” in step S1109 in FIG. The description of the flowchart of FIG. 11 is omitted because it has already been performed.

The frequency used by the antenna 1300 and the antenna 1310 is not particularly described, but may be the same frequency band as the antenna 13 or the antenna 14 or may be different. Moreover, what is necessary is just to use the predetermined value according to the frequency band to be used for the above-mentioned TH3 and TH4.
(5) In above-mentioned embodiment, although the alerting | reporting part 433 was supposed to alert | report a user by a vibration, it is enough if it can alert | report to a user. For example, the notification unit 433 may be configured by a voice processing LSI, and the user may be notified by generating a ringtone.

(6) In the above-described embodiment, the touch pad is based on a capacitive system that detects a touch operation by a user based on a change in electrostatic capacity. However, if the touch pad is based on a system that can detect a touch operation by the user. It ’s enough. For example, the touch pad may detect a touch operation by a resistance film method, a surface acoustic wave method, or the like.
(7) The portable terminal 1 shown by the above-mentioned embodiment and each modification is information terminals, such as what is called a smart phone, a tablet terminal device, a mobile telephone, and a tablet-type personal computer, as an example. Moreover, although the housing | casing 10 was formed using plastic resin, it is good also as comprising using lightweight materials, such as a magnesium alloy. In addition, the display unit 12 is configured by a liquid crystal display. However, any device having a function of displaying an image or the like may be used. For example, the display unit 12 may be configured by an organic EL display. Further, although the frame 21 is formed using resin, it is sufficient that the frame 21 is formed of a material capable of holding members such as the battery 22 and the circuit board 23. For example, the frame 21 is formed of a metal such as aluminum. It is good.

Moreover, the portable terminal 1 shall also be equipped with components, such as a speaker which a normal smart phone etc. have, a receiver, a microphone, a camera, and GPS. In addition, the mobile terminal 1 includes a telephone function, a data communication function, a camera photographing function, a current position acquisition function using GPS, a short-range wireless communication function, and the like that a normal information terminal has.
(8) In the above-described embodiment and modification, the antenna 13 and the antenna 14 are used for wireless communication using radio waves of 800 MHz band and 2 GHz band as an example, but radio waves of other frequency bands are used. It may be used for communication. The frequency band used by each antenna may be all different, or two or more antennas may use the same frequency band.

  (9) In the above-described embodiment and each modification, the portable terminal 1 is assumed to be used in such a posture that the ASP 1 is on the upper side when viewed from the user, but is not limited thereto. For example, an acceleration sensor or the like that can detect the orientation of the mobile terminal 1 with respect to the ground may be added to the mobile terminal 1 to detect the grip operation mode based on the posture detected by the acceleration sensor or the like. For example, when the antenna is arranged as shown in FIG. 12 and the acceleration sensor detects that the ASP 3 is on the upper side when viewed from the user, the reflection coefficients of the antenna 14 and the antenna 1300 are measured. Then, when only the reflection coefficient of the antenna 14 is equal to or greater than the threshold value, it is determined that the left-hand holding operation is performed.

(10) Each functional component shown in the above-described embodiment and each modification may be realized as a circuit that executes the function, or is realized by executing a program by one or a plurality of processors. Also good.
(11) The above-described embodiment and modifications may be partially combined.

  A portable terminal according to one embodiment of the present invention is suitable as a terminal such as a portable telephone or a smartphone that inputs information such as characters using a touch panel.

DESCRIPTION OF SYMBOLS 1 Mobile terminal 10 Case 11 Touch panel 12 Display part 13, 14 Antenna 21 Frame 22 Battery 23 Circuit board 401, 411, 1301, 1311 Transmission / reception part 402, 412, 1302, 1312 Circulator 403, 413, 1303, 1313 Reflection coefficient measurement part 404, 414, 1304, 1314 Bidirectional coupler 421 Control unit 431 Input unit 432 Storage unit 433 Notification unit 434 Timer unit 501 Software keyboard image 511 R image 512 L image 513 B image

Claims (7)

Of the pair of opposing side walls having a display unit, the first antenna is arranged in the casing near one side wall, and the second antenna is arranged in the casing near the other side wall. A portable terminal,
A reflection coefficient measuring unit for measuring a reflection coefficient of each of the first and second antennas;
A determination unit for determining whether or not each of the reflection coefficients measured by the reflection coefficient measurement unit is equal to or greater than a threshold;
A portable terminal comprising: a display processing unit that switches a display position of a display object to be displayed on the display unit based on a determination result by the determination unit. The portable terminal according to claim 1, wherein the display processing unit switches the display position according to a gripping form of the housing estimated from a determination result by the determination unit. The display processing unit determines that only the reflection coefficient of the first antenna is greater than or equal to a threshold value when the display unit displays a software keyboard for a user to input information on the screen as the display object. The software keyboard is displayed close to the one side wall, and when the determination unit determines that only the reflection coefficient of the second antenna is greater than or equal to a threshold value, the software keyboard is moved to the other side wall. The mobile terminal according to claim 1, wherein the mobile terminal is displayed near the screen. The reflection coefficient measurement unit repeatedly measures the reflection coefficient of each of the first and second antennas,
Each time the reflection coefficient is measured by the reflection coefficient measurement unit, the determination unit determines whether the measured reflection coefficient is equal to or greater than a threshold value, respectively.
The display control unit displays on the display unit when a gripping form of the casing estimated from a determination result by the determination unit is different from a gripping form of the casing estimated from a previous determination result. The mobile terminal according to claim 1, wherein the display position of the display object to be switched is switched according to a gripping form of the casing estimated from the current determination result. The reflection coefficient measurement unit measures the first and second antennas as traveling waves with respect to the first and second antennas when measuring the reflection coefficients of the first and second antennas. The portable terminal according to claim 1, wherein a carrier wave having a smaller amplitude than that used when wireless communication is performed is used. Of the pair of opposing side walls having a display unit, the first antenna is arranged in the casing near one side wall, and the second antenna is arranged in the casing near the other side wall. Display method executed by the mobile terminal,
A reflection coefficient measuring step for measuring a reflection coefficient of each of the first and second antennas;
A determination step of determining whether or not each of the reflection coefficients measured in the reflection coefficient measurement step is equal to or greater than a threshold;
A display processing step of switching a display position of a display object to be displayed on the display unit based on a determination result of the determination step. The computer includes a display unit, and a first antenna is disposed in a casing near one of the pair of opposing side walls constituting the casing, and a second antenna is disposed in the casing near the other side wall. A display program for functioning as a mobile terminal provided with an antenna,
The computer,
Reflection coefficient measuring means for measuring the reflection coefficient of each of the first and second antennas;
Determining means for determining whether or not each of the reflection coefficients measured by the reflection coefficient measuring unit is equal to or greater than a threshold;
A display program for causing a display processing unit to switch a display position of a display object to be displayed on the display unit based on a determination result by the determination unit.

Images