JP2012085104A - Mobile terminal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mobile terminal device 1 capable of short-range radio communication that may make a user feel humor.SOLUTION: A mobile terminal device 1 comprises: a display unit 13 that can be set to a see-through state in which scenery in the background can be seen; a display control unit 100 for controlling the display unit 13; and a transmission unit 106 for transmitting object information by means of short-range radio communication. The display control unit 100 displays an image corresponding to the object information on the display unit 13 and sets a display area other than the image on the display unit 13 to the see-through state. The transmission unit 106 transmits the object information based on transmission operation for the image.

Description

  The present invention relates to a mobile terminal device such as a mobile phone or a PDA (Personal Digital Assistant).

  2. Description of the Related Art Conventionally, a portable terminal device provided with a short-range wireless communication function for transmitting / receiving information to / from an information communication device at a short distance is known. In this type of portable terminal device, various modes can be adopted as an operation mode for transmitting information to be transmitted (target information). For example, when the mobile terminal device is tilted with the target information selected, the receiving terminal is recognized and the target information is transmitted to the receiving terminal (for example, Patent Document 1).

WO2007 / 034787

  In such a portable terminal device, it is desired not only to transmit and receive target information but also to realize short-range wireless communication that can make the user feel interesting by devising an operation mode.

  The present invention has been made in view of such problems, and an object thereof is to provide a portable terminal device capable of short-range wireless communication that can make a user feel interesting.

  A mobile terminal device according to a main aspect of the present invention includes a display unit that can be set in a see-through state in which a landscape behind can be viewed, a display control unit that controls the display unit, and target information transmitted by short-range wireless communication A transmission unit. Here, the display control unit displays an image corresponding to the target information on the display unit, sets a display area other than the image in the display unit to the see-through state, and the transmission unit applies to the image The target information is transmitted based on a transmission operation.

  According to the mobile terminal device according to this aspect, the display area other than the image corresponding to the target information is set to the see-through state. For this reason, the transmission partner can be seen through the image corresponding to the target information. In this state, the user can obtain a sense of sending the target information toward the reception-side terminal that looks over the image by performing a transmission operation on the image. This can make the user feel interesting.

  Moreover, according to the portable terminal device which concerns on this aspect, a user can arrange | position a portable terminal device smoothly in the vicinity of a receiving side terminal because a user views a receiving side terminal through the display area of a see-through state.

  The portable terminal device of the present invention may further include a position detection unit that detects a position on the display unit indicated by the user. Here, the transmission unit transmits target information corresponding to the image at the position detected by the position detection unit.

With such a configuration, the user can freely select and transmit target information to be transmitted. In addition, since the user shows the image from the front side of the display unit, the target information is transmitted to the receiving side terminal on the back side of the display unit, so that a sense of sending the target information toward the receiving side terminal can be more easily obtained.

  The portable terminal device of the present invention may include a first unit, a first position where the first unit overlaps, and a second unit movable to a second position next to the first unit. Here, the display unit includes a first display unit that is set to the see-through state and a second display unit that is not set to the see-through state, and the first display unit is set to the first unit. The second display unit is set in the second unit.

  In this case, the display control unit displays the image on the first display unit in a state where the second unit is positioned at the second position, and displays other than the image information on the first display unit. A region may be set to the see-through state.

  With such a configuration, when the second unit is positioned at the second position, the second unit does not overlap the first unit. For this reason, when the 1st display part of the 1st unit is set to a see-through state, what is behind the 1st unit can be visually recognized from the display area of a see-through state. Therefore, when the first unit is held over the receiving terminal, the receiving terminal can be confirmed through the display area in the see-through state.

  In the mobile terminal device of the present invention, the transmission unit is provided on a back surface of the second unit.

  With this configuration, when the user places the first unit on the receiving side terminal and sees the receiving side terminal from the see-through display area, the transmitting unit on the back of the first unit is the receiving side terminal. Facing each other. Therefore, in directional communication such as infrared communication, a communication signal can be transmitted from the back surface of the first unit to the receiving terminal in front.

  According to the mobile terminal device according to this aspect, the mobile terminal device may further include a receiving unit that receives information by short-range wireless communication. Here, the receiving unit is provided in front of the second unit.

  With this configuration, when the receiving terminal is arranged on the second unit, the receiving unit on the front surface of the second unit faces the receiving terminal. Therefore, when a communication signal is issued from the receiving terminal to the second unit, the communication signal can be received by the receiving unit of the second unit.

  In this case, the display control unit displays an image associated with the information received by the receiving unit on one of the first display unit and the second display unit.

  With such a configuration, an image associated with the received information is displayed on the first display unit or the second display unit, so that it is immediately understood that the information has been received.

  As described above, according to the present invention, it is possible to provide a mobile terminal device capable of short-range wireless communication that can make a user feel interesting.

  The effects and significance of the present invention will become more apparent from the following description of embodiments. However, the embodiment described below is merely an example when the present invention is implemented, and the present invention is not limited to what is described in the following embodiment.

It is a perspective view which shows the whole portable terminal device which concerns on embodiment. It is a perspective view which shows the whole portable terminal device which concerns on embodiment. It is sectional drawing which shows the portable terminal device which concerns on embodiment. It is a perspective view for demonstrating operation | movement of the portable terminal device which concerns on embodiment. It is a block diagram which shows the circuit of the portable terminal device which concerns on embodiment. It is a flowchart which shows the process sequence which displays the message which concerns on embodiment. It is a figure which shows the state which displays a message on the 1st display surface which concerns on embodiment. It is a figure which shows the state which displays a message on the 1st display surface which concerns on embodiment.

  Hereinafter, the mobile terminal device 1 according to the present embodiment will be described with reference to the drawings.

<Configuration of mobile terminal device>
FIG. 1A is a perspective view of the front side of the mobile terminal device 1 showing a state in which the first unit 10 is overlaid on the second unit 20. FIG. 1B is a perspective view of the front side of the mobile terminal device 1 showing a state in which the first unit 10 and the second unit 20 are arranged. FIG. 2 is a perspective view of the back side of the mobile terminal device 1 showing a state in which the first unit 10 and the second unit 20 are arranged. FIG. 3A is a cross-sectional view taken along line AA ′ of FIG. FIG. 3B is a cross-sectional view taken along line BB ′ in FIG. In the present embodiment, the surface on which the display surfaces 16b and 27b are arranged is referred to as the front surface of the units 10 and 20, and the surface facing the front surface is referred to as the back surface of the units 10 and 20.

  The mobile terminal device 1 is a portable computer having a short-range wireless communication function such as a mobile phone, a PDA, or a mobile game machine. The mobile terminal device 1 includes a first unit 10 and a second unit 20.

  The first unit 10 is overlaid on the second unit 20 and is slidable with respect to the second unit 20. The first unit 10 includes a first bottom portion 11.

  The first bottom portion 11 has a rectangular shape and is formed by injection molding using a transparent resin such as polycarbonate or acrylic. The first bottom portion 11 is provided with two bottom through holes 11a spaced from each other. The bottom through-hole 11a is elongated and extends in the direction in which the first unit 10 slides. The slide portion 12 is fitted in the bottom through hole 11a.

  The slide portion 12 has a main body portion of an elongated member. The main body portion is fitted in the bottom through hole 11a and is disposed above the second lid portion 27 described later. The slide part 12 has an insertion hole 12a in the middle part of the main body part, and has a locking part 12b at the end part of the main body part. The locking portion 12b protrudes into the second lid portion 27 through the bottom through hole 11a and a guide hole 27a described later. A through hole 12c is formed in the locking portion 12b. The through hole 12c penetrates from the upper surface of the main body portion to the side surface of the locking portion 12b, and connects the first unit 10 and the second unit 20 inside. A first display portion 13 is disposed on the first bottom portion 11 between the two slide portions 12.

  The 1st display part 13 is a rectangular flat plate shape, Comprising: For example, it is comprised by the transparent liquid crystal display. The liquid crystal display includes a liquid crystal panel, and no backlight is arranged behind the liquid crystal panel. The liquid crystal panel has a normally white display mode. The liquid crystal panel is configured by sandwiching a transparent liquid crystal (not shown) and a transparent electrode (not shown) between two transparent plates (not shown). An electrode 13 a is provided at the end of the first display unit 13, and the first input unit 14 is overlaid on the first display unit 13.

  The electrode 13 a connects the transparent liquid crystal display and the wiring 15. A flexible substrate is used for the wiring 15. The wiring 15 passes through the through hole 12c of the locking portion 12b and goes into the second lid portion 27.

  The first input unit 14 is a touch sensor that detects the presence and position of contact by the user. The touch sensor is a transparent rectangular sheet, and two transparent electrodes (not shown) are incorporated in a matrix. Similar to the wiring 15 of the first display unit 13, the wiring of the first input unit 14 passes through the through hole 12 c of the locking unit 12 b and is guided into the second lid 27.

  The first lid portion 16 is placed on the first bottom portion 11 so as to cover the first input portion 14. The first lid portion 16 is formed by injection molding using a transparent resin such as polycarbonate or acrylic. A first display surface 16 b is formed on the first lid portion 16. The first display surface 16 b covers the first display unit 13 and is located in a range overlapping the first display unit 13 and the second display unit 25. The first lid portion 16 is provided with two lid through holes 16a. The lid through-hole 16a is provided on the bottom through-hole 11a, and the covering portion 17 is fitted into the lid through-hole 16a.

  The covering portion 17 is formed by injection molding using an opaque resin as a material. The covering portion 17 covers the slide portion 12 that fits in the bottom through hole 11a. The cover portion 17 is provided with a screw hole 17a. When the screw 18 is fitted into the screw hole 17a and the insertion hole 12a of the slide portion 12, the slide portion 12 and the covering portion 17 are connected in the vertical direction.

  By connecting the slide part 12 and the covering part 17, the first lid part 16 and the first bottom part 11 are fixed, and the first unit 10 is assembled.

  The second unit 20 includes a second bottom portion 21. The second bottom portion 21 has a rectangular shape and is approximately the same size as the first lid portion 16. A support portion 21 a is provided in the second bottom portion 21. The support portion 21a is an elongated ridge portion, and extends in the direction in which the first unit 10 slides. The receiving part 26 is arrange | positioned on the support part 21a.

  The receiving part 26 has a bottom plate and a side plate and extends in a direction in which the first unit 10 slides. The receiving portion 26 is disposed under the guide hole 27a and attached to the locking portion 12b protruding from the guide hole 27a.

  The battery 22 is disposed in the second bottom portion 21, and the substrate 23 is overlaid on the battery 22. On the surface of the substrate 23, a connector 23a and electronic components (not shown) such as a CPU and a memory are arranged. The connector 23a and the electronic component are connected by wiring (not shown). A connector 22 a is provided beside the battery 22. The connector 22 a is connected to the substrate 23 and the battery 22, and is connected to the wiring 15 of the first display unit 13 and the wiring of the first input unit 14. The second display unit 25 is stacked on the substrate 23.

  The 2nd display part 25 is comprised with the liquid crystal display which is not transparent, for example. The liquid crystal display includes a liquid crystal panel 25a and an illumination unit for illuminating the liquid crystal panel 25a. The liquid crystal panel 25a is configured by sandwiching a transparent liquid crystal (not shown) and a transparent electrode (not shown) between two transparent plates (not shown). The illumination unit includes a light guide plate 25b and a light emitting unit 25c. The light guide plate 25b is disposed beside the light emitting unit 25c and below the liquid crystal panel 25a so as to guide light from the light emitting unit 25c to the second display unit 25. The second input unit 24 is stacked on the liquid crystal panel 25a.

For example, a touch sensor is used as the second input unit 24. The touch sensor is a transparent rectangular sheet. In the touch sensor, two transparent electrodes (not shown) are incorporated in a matrix, and wiring (not shown) is connected to the transparent electrodes.

  Wirings (not shown) are arranged on the light emitting unit 25 c, the liquid crystal panel 25 a and the second input unit 24, respectively, and these wirings are connected to the substrate 23.

  The second lid portion 27 is connected to the second bottom portion 21 to form the second unit 20. A transparent display window is formed in the center of the second lid portion 27. The display window is the second display surface 27 b and covers the second display unit 25 and is located in a range overlapping the second display unit 25. The second lid portion 27 is provided with two guide holes 27a spaced apart from each other. The first unit 10 and the second unit 20 are connected by the locking portion 12b passing through the guide hole 27a being locked to the edge of the second lid portion 27 surrounding the guide hole 27a.

<Operation of the mobile terminal device 1>
FIG. 4A is a perspective view showing the wiring 15 when the first unit 10 and the second unit 20 are overlaid. FIG. 4B is a perspective view showing the wiring 15 when the first unit 10 and the second unit 20 are arranged. 4A and 4B, some parts such as the first lid portion 16 are represented by broken lines so that the state of the wiring 15 can be easily understood.

  As shown in FIG. 1A, when the mobile terminal device 1 is folded and the first unit 10 overlaps the second unit 20, the first display surface 16b appears outside and the second display surface 27b is the first. Hidden under unit 10. Hereinafter, the state of the mobile terminal device 1 is referred to as a closed state, and the display form is referred to as a first form.

  In the first mode, as shown in FIG. 4A, the locking portion 12b of the slide portion 12 is positioned at one end of the guide hole 27a, that is, in the vicinity of the connector 23a of the substrate 23. The wiring 15 extends along the receiving portion 26 from the through hole 12c of the locking portion 12b, bends in the middle, returns to the through hole 12c along the receiving portion 26, and is connected to the connector 23a.

  On the other hand, as shown in FIG. 1B, when the mobile terminal device 1 is unfolded and the first unit 10 is pulled out to the side of the second unit 20, both the first display surface 16b and the second display surface 27b are used. Appears outside. At this time, the end of the first unit 10 slightly overlaps the end of the second display surface 27b, and the first display surface 16b and the second display surface 27b are arranged side by side with no gap. Less than. The state of the mobile terminal device 1 is referred to as an open state, and the display form is referred to as a second form.

  In the second mode, as shown in FIG. 4B, the locking portion 12b of the slide portion 12 moves from one end of the guide hole 27a to the other end, and the guide hole 27a opens. The locking portion 12b moves away from the position of the connector 23a on the board 23, and the wiring 15 extends linearly from the through hole 12c of the locking portion 12b to the connector 23a on the board 23.

  In addition, by switching to the first form and the second form, the second unit 20 has a first position that overlaps the first unit 10 in the first form and a second line that is arranged beside the first unit 10 in the second form. Move the position.

<Circuit of the mobile terminal device 1>
FIG. 5 is a block diagram of a circuit of the mobile terminal device 1.

The mobile terminal device 1 according to the present embodiment includes a CPU 100, a memory 101, a communication module 102, an open / close sensor 103, an orientation sensor 104, a clock 105,
A transmission unit 106 and a reception unit 107 are provided.

  The first display unit 13 and the second display unit 25 receive video signals from the CPU 100. By applying a voltage to the transparent electrodes of the display units 13 and 25 based on these video signals, the alignment of the liquid crystal changes, and the light passing through the liquid crystal is modulated. Thereby, each display part 13 and 25 displays images, such as illustrations, such as an icon and a keyboard, a photograph, a character, a picture, and a window. The image displayed by the first display unit 13 is displayed on the first display surface 16 b of the first lid unit 16 via the transparent first input unit 14. The image displayed by the second display unit 25 is displayed on the second display surface 27 b of the second lid 27 via the transparent second input unit 24. However, in the first embodiment, if the first display unit 13 is in a transparent state, the image displayed by the second display unit 25 is displayed on the first display surface 16b via the transparent first display unit 13. . For this reason, the image by the 1st display part 13 or the image by the 2nd display part 25 is displayed on the 1st display surface 16b.

  Moreover, in the 1st display part 13, in the range where the voltage is not applied, the transmittance | permeability becomes the maximum and light permeate | transmits. Here, since the first cover part 16, the first input part 14, and the first bottom part 11 sandwiching the first display part 13 are transparent, the light transmission range in the first display part 13 is transparent or translucent. Thus, a see-through state in which the scenery behind the first display unit 13 can be seen is obtained.

  Power from the battery 22 is supplied to the light emitting unit 25 c of the second display unit 25 by a control signal from the CPU 100. Thereby, the light emission part 25c light-emits. The emitted light enters the light guide plate 25b from the side surface of the light guide plate 25b, and a part of the light exits from the surface of the light guide plate 25b to the liquid crystal panel 25a side while being reflected inside the light guide plate 25b. Thereby, light is uniformly emitted from the entire light guide plate 25b, and the liquid crystal panel 25a is irradiated with light. Thereby, the image displayed on the 2nd display surface 27b becomes visible. In addition, although the light emission part is not provided in the 1st display part 13, the liquid crystal panel of the 1st display part 13 is illuminated with external light in the 1st form, and the light from the 2nd display part 25 in the 2nd form. Illuminated by. Thereby, the image displayed on the 1st display surface 16b becomes visible.

  The first input unit 14 detects a change in capacitance between the transparent electrodes. As a result, when the capacitance changes at a position where the user's finger or the like touches the first display surface 16b, the first input unit 14 outputs a signal corresponding to the contact position of the user to the CPU 100. Thereby, the position which the user showed with respect to the 1st display surface 16b is detectable. In the second form, since the image displayed by the first display unit 13 is displayed on the first display surface 16b, the first input unit 14 is positioned at the position indicated with respect to the image of the first display unit 13. Is detected. In the first form, when the image by the first display unit 13 is displayed on the first display surface 16b, the first input unit 14 detects the position indicated with respect to the image by the first display unit 13. To do. On the other hand, in the first form, when the first display unit 13 is transparent and the image by the second display unit 25 is displayed on the first display surface 16b, the first input unit 14 displays the second display. The position indicated with respect to the image by the unit 25 is detected.

  Similar to the first input unit 14, the second input unit 24 outputs a signal corresponding to a position touched by the user's finger or the like on the second display surface 27 b to the CPU 100. Thereby, the position which the user showed with respect to the 2nd display surface 27b is detectable. In both the first form and the second form, since the image displayed by the second display unit 25 is displayed on the second display surface 27b, the second input unit 24 displays the image of the second display unit 25. Detect the position indicated for.

  The battery 22 receives a control signal from the CPU 100 and supplies power to the CPU 100, the display units 13 and 25, the input units 14 and 24, and the like according to the control signal.

  The memory 101 is a storage unit including a ROM and a RAM. The memory 101 stores a control program for giving a control function to the CPU 100. For example, the memory 101 stores a control program for converting information into a signal for short-range wireless communication in accordance with a short-range wireless communication standard. The memory 101 stores text information, image information, and sound information in a predetermined file format. For example, image information of photographs and videos taken by a camera module (not shown), mail information such as image information and text information captured from the outside via the communication module 102, contact information such as name, telephone number, and mail address Information. Furthermore, the memory 101 stores images such as icons displayed on the display surfaces 16b and 27b in association with positions where icons are displayed.

  The open / close sensor 103 is disposed at a position close to the magnet in the first embodiment, and the magnet is disposed in the vicinity of the locking portion 12b. The open / close sensor 103 is connected to the substrate 23 by wiring and transmits / receives a signal to / from the CPU 100 of the substrate 23. When the magnet is present in the vicinity of the open / close sensor 103 in the first embodiment, the open / close sensor 103 detects the magnetic field of the magnet and outputs a detection signal to the CPU 100 indicating that the magnet is closed. On the other hand, when the magnet is separated from the open / close sensor 103 in the second embodiment, the open / close sensor 103 does not detect the magnetic field of the magnet and does not output a detection signal indicating that the magnet is closed to the CPU 100.

  The communication module 102 converts an audio signal, a video signal, a text signal, and the like from the CPU 100 into a radio signal and transmits it to the base station via the antenna. Further, the communication module 102 converts the received wireless signal into an audio signal, a video signal, a text signal, and the like and outputs the converted signal to the CPU 100.

  As the orientation sensor 104, a geomagnetic sensor or the like is used. The direction sensor 104 detects the direction in which the display units 13 and 25 are directed, and outputs a signal corresponding to the direction to the CPU 100.

  The clock 105 measures time and outputs a signal corresponding to the measured time to the CPU 100.

  The transmission unit 106 includes a generation unit (not shown) that emits an electromagnetic wave and a transmission window 106a that emits the electromagnetic wave to the outside. The transmission unit 106 receives the control signal from the CPU 100, generates a signal by modulating the electromagnetic wave from the generation unit based on the control signal, and radiates the signal from the transmission window 106a. Thereby, information is sent to the receiving side terminal by short-range wireless communication. Note that as the short-range wireless communication, a method of transmitting / receiving information to / from a receiving terminal located at a short distance using an electromagnetic wave, such as infrared communication and Bluetooth (registered trademark), is used. Moreover, the transmission window 106a is provided in the back surface of the 2nd unit 20, as shown in FIG. For this reason, the electromagnetic wave is irradiated forward of the back surface of the second unit 20. The transmission window 106 a is provided at a position close to the first unit 10 in the back surface of the second unit 20 in the mobile terminal device 1 of the second form. Further, the transmission window 106a is provided at the center of the combined range of the first unit 10 and the second unit 20 or at a position close to the center.

  The receiving unit 107 includes a receiving window 107a and a receiving unit (not shown) that receives electromagnetic waves that have passed through the receiving window 107a. The receiving unit 107 detects the modulated electromagnetic wave, converts the electromagnetic wave detection signal into an electric signal, and outputs the electric signal to the CPU 100. Thereby, information is obtained from the receiving side terminal by short-range wireless communication. The reception window 107a is provided in front of the second unit 20 as shown in FIG. For this reason, the electromagnetic wave irradiated from the front ahead of the 2nd unit 20 is detected.

  As a display control unit that controls the display unit, the CPU 100 displays an image on each of the display units 13 and 25, sets the first display unit 13 in a see-through state, or lights the second display unit 25. To do.

  That is, the CPU 100 acquires text information and image information by reading from the memory 101 or receiving via the communication module 102. The CPU 100 outputs the information as a video signal to each of the first display unit 13 and the second display unit 25, and displays an image on each of the display surfaces 16b and 27b.

  Further, the CPU 100 outputs a control signal for adjusting the power supplied from the battery 22 to the first display unit 13, thereby controlling the voltage applied to the transparent electrode and changing the transmittance of the first display unit 13. . As a result, the CPU 100 sets the display area other than the image displayed by the first display unit 13 to the see-through state.

  Furthermore, when displaying an image on the second display unit 25, the CPU 100 supplies power from the battery 22 to the light emitting unit 25c, and causes the light emitting unit 25c to emit light.

  The CPU 100 generates a control signal for converting information into a short-range wireless communication signal in accordance with a communication standard for short-range wireless communication, and outputs the control signal to the transmission unit 106. In addition, the CPU 100 receives an electrical signal from the receiving unit 107 in accordance with a communication standard for short-range wireless communication, converts the electrical signal into information, and stores the information in the memory 101.

<Functions of the mobile terminal device 1>
FIG. 6 shows a processing procedure of the mobile terminal device 1 (hereinafter referred to as a transmission-side terminal) that transmits information by infrared communication and a process of the mobile terminal device 1 (hereinafter referred to as a reception-side terminal) that receives information. It is a flowchart which shows a procedure. FIG. 7 shows a transmission-side terminal that displays an image for selecting information to be transmitted by infrared communication on the first display surface 16b. FIG. 8 shows a state in which information is transmitted from the transmitting terminal to the receiving terminal.

  In the transmission side terminal, the operation menu is displayed on the first display surface 16b or the second display surface 27b. When the user touches the position of the infrared transmission icon from the operation menu, a function for transmitting information by infrared communication is selected, and a control program for the infrared transmission function is activated.

  First, the CPU 100 determines whether or not the transmission side terminal is in the second form (S101). Here, if a detection signal indicating that it is closed from the open / close sensor 103 is input, the CPU 100 indicates that the transmitting terminal is in a closed state, and this display form adopts the first form and is not the second form. Judgment is made (S101: NO). Then, the CPU 100 reads predetermined warning information from the memory 101, and a warning such as “Please open the mobile terminal device” is displayed on the first display surface 16b. The warning prompts the user for the sending terminal to take the second form.

  On the other hand, if the detection signal indicating that the opening / closing sensor 103 is closed is not input, the CPU 100 determines that the transmitting terminal is in the open state and the display form is the second form (S101: YES). ). In this way, since the transmitting terminal is in the second form, nothing overlaps with the first unit 10, so that the landscape behind can be seen from the transparent range of the first unit 10. .

Next, as shown in FIG. 7, the CPU 100 displays the candidates for the transmission target group on the second display surface 27b (S103). The transmission target group is a group of information stored in the memory 101 that can be transmitted by infrared communication for each type, such as contact information, photos, and emails.

  The CPU 100 waits for a transmission target group to be selected from the transmission target group candidates on the second display surface 27b (S104). For example, when the position of “photograph” is detected on the second display surface 27b, the CPU 100 determines that the transmission target group of “photograph” has been selected (S104: YES).

  Subsequently, the CPU 100 reads the image information A to F of the photograph from the memory 101, and displays the images of the photographs A to F on the first display surface 16b as transmission target information candidates as shown in FIG. 8 (S105). . At this time, the images of the photographs A to F are displayed as thumbnails, so that the contents of the images can be easily understood. Further, on the first display surface 16b, the display area other than the images of the photographs A to F is set to the see-through state. For this reason, when the first unit 10 of the transmission side terminal is placed over the reception side terminal that is a partner to which the image is to be transferred, the user passes the reception side terminal behind the first unit 10 through the display area in the see-through state. Visible.

  The user touches the image of the photograph A displayed on the first display surface 16b with a predetermined operation in a state where the transmission-side terminal is arranged at a position where the reception-side terminal can be seen through the first display surface 16b. Thereby, the CPU 100 determines that the photo A at the touched position is selected as the target information to be transmitted (S106: YES). The predetermined operation is, for example, an operation of touching the display position of the transmission target information twice in succession without a gap, or an operation of drawing a circle or the like while touching the display position of the transmission target information. Since the operation for selecting such transmission target information is different from the operation for selecting other information, it is possible to prevent other information from being erroneously transmitted. Further, as shown in FIG. 8, transmission target group candidates are displayed on the second display surface 27b.

  Then, the CPU 100 reads out the information of the image A corresponding to the image of the selected photo A from the memory, converts the information of the photo A into an infrared signal, and transmits the infrared signal from the transmission unit 106 (S107). . Thereby, infrared rays are emitted from the transmission window 106 a provided on the back surface of the second unit 20 toward the reception-side terminal behind the first unit 10. Note that the information of the photograph A includes, in addition to the image information of the photograph A, attached information indicating the display state at the transmitting terminal. The attached information includes information indicating whether the photograph A is displayed in a thumbnail, a file name, an icon, and the like, information on the display size of the photograph A on the display surface 16b, and an orientation in which the photograph A is displayed. There is information. The orientation in which the photograph A is displayed is obtained from the orientation of the display surface 16b detected by the orientation sensor 104.

  On the other hand, in the receiving terminal, an operation menu is displayed on the first display surface 16b or the second display surface 27b. When the user touches the position of the infrared reception icon from the operation menu, the function for receiving information by infrared communication is selected, and the control program for the infrared reception function is activated.

  In response to the signal from the clock 105, the CPU 100 starts measuring the elapsed time (S201).

  The receiving unit 107 receives infrared rays irradiated from the front front of the second unit 20. In this case, the front surface of the second unit 20 of the receiving terminal faces the back surface of the second unit 20 of the transmitting terminal. For this reason, the infrared rays emitted from the transmission unit 106 on the back surface of the second unit 20 of the transmission side terminal are received by the reception unit 107 on the front side of the second unit 20 of the reception side terminal.

The CPU 100 determines whether or not the information sent from the transmission side terminal, in this example, the information of the photograph A has been received (S202). Here, when the receiving unit 107 detects infrared rays, C
The PU 100 receives the infrared detection signal from the receiving unit 107. The CPU 100 determines that the image of the photograph A has been received if the infrared detection signal from the receiving unit 107 can be converted into the information of the photograph A according to the communication standard of the short-range wireless communication (S201: YES).

  The CPU 100 extracts image information and attached information from the acquired information of the photograph A. The CPU 100 generates an image of the photograph A from the image information, and obtains a display mode, a display size, and a display direction of the image of the photograph A on the transmission side terminal from the attached information. The CPU 100 displays the image of the photograph A on the display surface 16b of the reception side terminal in the same display mode, display size, and display direction as the transmission side terminal (S203).

  On the other hand, when the receiving unit 107 cannot receive part or all of the infrared signal related to the information of the photograph A and the CPU 100 cannot convert the infrared detection signal into the information of the photograph A, the CPU 100 displays the image of the photograph A. Is not received (S202: NO).

  The CPU 100 determines whether or not the measurement time has passed a predetermined time (S204). Here, until the measurement time has passed the predetermined time, the CPU 100 determines again whether or not the receiving unit 107 has received all the infrared signals related to the image of the photograph A (S202). On the other hand, when the measurement time has elapsed, the predetermined error message information is read from the memory 101 and displayed on the second display surface 27b.

  As described above, according to the present embodiment, the display area other than the transmission target information is set to the see-through state while the transmission target information is displayed on the first display surface 16b. Thereby, the user can see the receiving side terminal that is the transmission destination of the infrared communication through the image corresponding to the transmission target information through the display area in the see-through state. In this state, the user can obtain a sense of sending the target information toward the receiving terminal that can be seen through the image by performing a transmission operation on the image. This can make the user feel interesting.

  Further, according to the present embodiment, the information of the photograph A (transmission target information) includes image information and display information on the transmission side terminal. Thereby, also in the receiving side terminal, the image of the photograph A can be displayed on the display surface in the same display state as the transmitting side terminal. Therefore, it looks as if the image of the photograph A has jumped from the transmission side terminal to the reception side terminal. Therefore, the user can be more interesting in the short-range wireless communication.

  Further, according to the present embodiment, the transmission unit 106 is provided on the back surface of the second unit 20, and the reception unit 107 is provided on the front surface of the second unit 20. For this reason, the transmission unit 106 and the reception unit 107 are automatically arranged at positions facing each other simply by arranging the transmission side terminal at a position where the user views the reception side terminal through the see-through display area. Thereby, the user does not need to worry about the positional relationship between the transmission unit 106 and the reception unit 107. In particular, for a user who does not know the position of the communication port, it is possible to easily match the positional relationship between the transmission unit 106 and the reception unit 107 without searching for the positions of the transmission unit 106 and the reception unit 107 and adjusting them.

  Furthermore, according to the present embodiment, the transmission window 106a is provided at the center of the combined range of the first unit 10 and the second unit 20 or at a position close to the center. Thus, even if the orientation of the display surfaces 16b and 27b is rotated with respect to the axis perpendicular to the display surfaces 16b and 27b, the position of the transmission window 106a hardly changes. Therefore, the orientation of the mobile terminal device 1 can be freely changed.

<Other embodiments>
Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications other than those described above can be made to the embodiments of the present invention. .

  According to the embodiment, the transmission unit 106 and the reception unit 107 are provided in the second unit 20, but the transmission unit 106 and the reception unit 107 may be provided in the first unit 10.

  Moreover, although the same portable terminal device 1 as a transmission side was used for the receiving side terminal in the said embodiment, the computer which has near field communication functions, such as a personal computer, can also be used.

  Furthermore, in the above embodiment, the target information to be transmitted is displayed as a thumbnail image, but the display mode of the transmission target information is not limited to this, and any image corresponding to the transmission target information may be used. For example, the CPU can extract the file name from the transmission target information and display an image indicating the file name on the first display unit 13. The CPU can also extract a file format from the transmission target information and display an icon associated with the file format on the first display unit 13.

  Further, according to the above-described embodiment, as shown in FIG. 8, when the image on the photo A is touched and selected as target information to be transmitted at the transmission side terminal, the transmission target group is displayed on the second display surface 27b. Candidates are displayed. On the other hand, the content displayed on the 2nd display surface 27b is not limited to this. For example, the CPU 100 can enlarge and display the image of the photograph A on the second display surface 27b. Further, the detailed information of the photo A may be displayed on the second display surface 27b together with the enlarged image of the photo A. The detailed information of the photograph A includes the shooting date and time, the location, the image procedure, and the like. As described above, the information related to the photograph A such as the enlarged image and the detailed information is displayed on the second display surface 27b, so that the user can know more specifically about the image to be transmitted.

  In the above-described embodiment, the display information such as the display size and the display direction is attached to the information of the photograph A, but the information may not be attached. Alternatively, the display information may further include the position information of the transmission side terminal and the display position information of the image of the photo A on the transmission side terminal. In this case, the relative position between the transmitting terminal and the receiving terminal is obtained from the positional information of the transmitting terminal and the positional information of the receiving terminal. From this relative position and the display position of the photo A on the transmission side terminal, the display position of the photo A displayed on the reception side terminal is obtained.

  Moreover, according to the said embodiment, the notification of whether the receiving side terminal received information can also be transmitted to a transmitting side terminal. As a result, it can be determined whether or not the transmission of information is successful at the transmitting terminal.

  In addition, the embodiment of the present invention can be variously modified as appropriate within the scope of the technical idea shown in the claims.

DESCRIPTION OF SYMBOLS 1 ... Portable terminal device 10 ... 1st unit 13 ... 1st display part 14 ... 1st input part 20 ... 2nd unit 24 ... 2nd input part 25 ... 2nd display part 100 ... CPU
106 ... Transmitter 107 ... Receiver

Claims (7)

A display unit that can be set to a see-through state in which the landscape behind can be seen,
A display control unit for controlling the display unit;
A transmission unit for transmitting the target information by short-range wireless communication,
The display control unit displays an image corresponding to the target information on the display unit, sets a display area other than the image in the display unit to the see-through state,
The transmission unit transmits the target information based on a transmission operation for the image.
The portable terminal device characterized by the above-mentioned. The mobile terminal device according to claim 1,
A position detection unit for detecting a position on the display unit indicated by the user;
The transmission unit transmits target information corresponding to the image at the position detected by the position detection unit;
The portable terminal device characterized by the above-mentioned. The mobile terminal device according to claim 1 or 2,
A first unit;
A first position where the first unit overlaps, and a second unit movable to a second position next to the first unit,
The display unit includes a first display unit set to the see-through state and a second display unit not set to the see-through state,
The first display unit is set in the first unit,
The second display unit is set in the second unit.
The portable terminal device characterized by the above-mentioned. The mobile terminal device according to claim 3.
The display unit control
In the state where the second unit is positioned at the second position, the target information is displayed on the first display unit, and the display unit other than the target information on the first display unit is set to the see-through state. ,
The portable terminal device characterized by the above-mentioned. The mobile terminal device according to claim 3 or 4,
The transmitter is provided on the back surface of the second unit.
The portable terminal device characterized by the above-mentioned. The portable terminal device according to any one of claims 3 to 5,
A receiver that receives information by short-range wireless communication;
The receiver is provided in front of the second unit.
The portable terminal device characterized by the above-mentioned. The mobile terminal device according to claim 6,
The display control unit displays an image associated with the information received by the receiving unit on either the first display unit or the second display unit.
The portable terminal device characterized by the above-mentioned.

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